CN209827984U - Biological rhythm self-adaptive adjusting device - Google Patents

Abstract

The utility model discloses a biological rhythm self-adaptive adjusting device, which comprises a parameter acquisition component, a control component and a rhythm adjusting component, wherein the parameter acquisition component and the rhythm adjusting component are in communication connection with the control component; the parameter acquisition component is used for acquiring physiological parameters of a user in real time and transmitting the acquired physiological parameters to the control component in real time; the biological rhythm self-adaptive adjusting device also comprises a communication component connected with the control component, and the communication component is used for transmitting the environment information and/or the user characteristic information of the user acquired from the intelligent terminal to the control component; the control component is used for controlling the rhythm regulation component in real time according to the environmental information and/or the user characteristic information and the physiological parameters acquired from the parameter acquisition component so as to enable the rhythm regulation component to act on a user. The individual physical sign state of the user and/or the environmental factors of the user are used as the basis for adjusting the biological rhythm, so that the biological rhythm self-adaptive adjustment is more targeted and has better adjustment effect.

Description

Biological rhythm self-adaptive adjusting device

Technical Field

The utility model relates to a healthy product field of intelligence especially relates to a biological rhythm self-adaptation adjusting device.

Background

Modern medicine places more and more importance on the influence of the environment on human health, more and more importance on the scientific health preservation of related people, and some devices are also appeared to regulate the biological rhythm of human body by various means such as light stimulation and the like. However, the existing devices only use a single physiological parameter of the human body as the adjustment basis, and neglect some other factors that can affect the biological rhythm, such as user characteristics of the user, such as age, sex, occupation, etc., so the adjustment devices of the type lack pertinence to the adjustment of the biological rhythm of the user, and have poor effect.

SUMMERY OF THE UTILITY MODEL

In order to overcome the deficiency of the prior art, the utility model aims to provide a biological rhythm self-adaptation adjusting device can acquire the information of user's environment and/or user's individual sign state as the basis that biological rhythm adjusted, and biological rhythm self-adaptation adjusting has more to have pertinence, and the regulating effect is better.

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

a biological rhythm self-adaptive adjusting device comprises a parameter acquisition component, a control component and a rhythm adjusting component, wherein the parameter acquisition component and the rhythm adjusting component are in communication connection with the control component;

the parameter acquisition assembly is used for acquiring physiological parameters of a user in real time and transmitting the acquired physiological parameters to the control assembly in real time;

the biological rhythm self-adaptive adjusting device also comprises a communication component connected with the control component, and the communication component is used for transmitting the environment information and/or the user characteristic information of the user acquired from the intelligent terminal to the control component;

the control component is used for controlling the rhythm regulating component in real time according to the environmental information and/or the user characteristic information and the physiological parameters acquired from the parameter acquisition component, so that the rhythm regulating component acts on a user.

In some embodiments, the adaptive circadian rhythm control device further comprises an interactive component connected to the control component, and the interactive component is used for acquiring user characteristic information of a user and transmitting the acquired user characteristic information to the control component.

In some embodiments, the parameter collecting assembly includes at least one of an electrocardiograph unit for obtaining electrocardiographic parameters of a user, a body temperature unit for obtaining body temperature of the user, a humidity unit for obtaining skin humidity of the user, an impedance unit for obtaining skin impedance of the user, a respiration unit for obtaining respiration rate of the user, a blood oxygen unit for obtaining blood oxygen saturation of the user, a heart rate unit for obtaining heart rate of the user, a pulse wave unit for obtaining pulse waves of the user, a blood pressure unit for obtaining blood pressure of the user, and an electroencephalograph unit for obtaining electroencephalogram parameters of the user.

In some embodiments, the electrocardiograph unit, the body temperature unit, the humidity unit, the impedance unit, the respiration unit, the blood oxygen unit, the heart rate unit, the pulse wave unit, the blood pressure unit and/or the electroencephalograph unit are in communication connection with the control component in a wired manner or a wireless manner.

In some embodiments, the rhythm regulation component includes: at least one of a gas pressure unit, an electrical stimulation unit, a light emitting unit and a sound unit.

In some embodiments, the gas pressure unit, electrical stimulation unit, light emitting unit, and/or sound unit are communicatively coupled to the control assembly in a wired or wireless manner.

In some embodiments, the gas pressure unit comprises an inflatable single-chamber airbag or multi-chamber airbag which is wrapped on a preset part of the human body;

the electrical stimulation unit comprises an electrode clip for clipping on an ear;

the light emitting unit comprises one light emitting element or a plurality of light emitting elements with different wavelengths; the light-emitting element emits light with a wavelength of 300nm to 3000 nm.

In some embodiments, the biorhythm adaptive adjustment device further comprises a frame-like body including a frame and a temple connected to the frame;

the electric stimulation unit and/or the sound unit and the control component are positioned on the glasses legs, and the light-emitting unit is positioned on the glasses frame.

In some embodiments, the body temperature unit, impedance unit, and/or blood oxygen unit are located on the temple.

In some embodiments, the body temperature unit includes a temperature sensor, the impedance unit includes a skin impedance sensor, and the blood oxygen unit includes a photo-oximetry pulse sensor.

Compared with the prior art, the utility model discloses beneficial effect lies in: the embodiment of the utility model provides a biological rhythm self-adaptation adjusting method, through the environmental information that user characteristic information and/or user that acquire located to and the real-time physiological parameter real-time control rhythm regulation subassembly 300 of the user who acquires, so that rhythm regulation subassembly 300 acts on the user, with the individual sign state of user and/or the environmental factor that the user located as the basis that biological rhythm was adjusted, therefore biological rhythm self-adaptation adjusting has more pertinence, and the regulating effect is better.

Drawings

Fig. 1 is a schematic flow chart of a biological rhythm adaptive adjustment method according to an embodiment of the present invention;

fig. 2 is another schematic flow chart of a biological rhythm adaptive adjustment method according to an embodiment of the present invention;

FIG. 3 is a schematic sub-flow diagram of the real-time control rhythm regulation module of FIG. 1;

fig. 4 is a schematic flow chart of a biorhythm adaptive adjustment method according to a first embodiment of the present invention;

fig. 5 is a schematic structural diagram of a biorhythm adaptive adjustment device according to a second embodiment of the present invention;

fig. 6 is another schematic structural diagram of a biorhythm adaptive adjustment device according to a second embodiment of the present invention;

fig. 7 is a schematic structural diagram of the control assembly in fig. 5.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict.

Example one

Fig. 1 is a schematic flow chart of a method for adaptively adjusting biological rhythms.

The adaptive regulation method of the biological rhythm comprises the following steps:

step S110, obtaining the user characteristic information of the user.

In some possible embodiments, the user characteristic information of the user is obtained through an interactive component of the adjusting device, such as a touch screen, a voice input module, and the like, which applies the biorhythm adaptive adjusting method.

In other possible embodiments, the adjusting device applying the adaptive biorhythm adjusting method may communicate with a smart terminal, such as a mobile phone, in a wired or wireless manner, so that the user characteristic information of the user may be obtained through the communication component of the adjusting device.

In some possible embodiments, after the user sets the user characteristic information at a certain time, the user characteristic information is saved to the memory of the adjusting device; the next time the user uses the adjustment device, the user characteristic information of the user is obtained from the memory.

In some possible embodiments, the user characteristic information includes at least one of age, gender, occupation, lifestyle habits, illness, medication, diet, sleep, and the like of the user. User characteristic information can embody user's sign state, the embodiment of the utility model provides a also as the foundation that follow-up biorhythm adjusted with user's user characteristic information. For example, user characteristic information set by a certain user includes age of 60 or more, chronic disease, dreaminess, use of a certain drowsy drug, and/or less than 6 hours of sleep, etc., and such information is subsequently applied and valued in controlling the rhythm regulation component so that the rhythm regulation component acts on the user.

And step S120, acquiring the physiological parameters of the user in real time.

Specifically, the physiological parameters of the user are collected using a parameter collection assembly.

In some possible embodiments, the adjusting device applying the biological rhythm self-adaptive adjusting method is provided with a parameter acquisition component, for example, the parameter acquisition component is arranged on the body of the spectacle frame type adjusting device; in other possible embodiments, the adjusting device using the adaptive biological rhythm adjusting method may not have a parameter collecting component, but may be connected to an external parameter collecting component through communication, and the external parameter collecting component collects the physiological parameters of the user and then sends the collected physiological parameters to the electronic device.

In some possible embodiments, the step S120 of acquiring the physiological parameter of the user in real time specifically includes: and acquiring at least one of the electrocardio parameters, the body temperature, the skin humidity, the skin impedance, the respiratory rate, the blood oxygen saturation, the heart rate, the pulse wave, the blood pressure and the electroencephalogram parameters of the user in real time.

In some possible embodiments, the acquisition of the corresponding physiological parameter of the user by each unit in the parameter acquisition assembly may be specifically obtained by:

electrocardio parameters: the sensor electrodes are used for collecting the signals from the body surface of a human body, and can be positioned on an external parameter collecting assembly and a self-contained parameter collecting assembly.

Body temperature: the temperature sensors are collected on the skin surface and may also be integrated in a spectacle-type device, such as a temple.

Skin moisture: the moisture sensors may be integrated on a glasses-type device, such as a temple, by collecting on the skin surface through the moisture sensors.

Skin impedance: the skin impedance values are measured on the skin surface by means of metal electrode sensors, which may also be integrated in a spectacle-type device, such as a temple.

Breathing rate: the electrode or the respiration sensor can be positioned on a parameter acquisition component connected with the outside of the adjusting device; the estimated value of the respiration rate can also be calculated by filtering and analyzing the electrocardio data and the blood oxygen data, and the sensor for acquiring the blood oxygen data can be integrated on a glasses type device, such as a glasses leg, in an exemplary manner of analyzing and estimating the blood oxygen data.

Oxygen saturation of blood: the measurement sensor probe and the adjusting device applying the biological rhythm self-adaptive adjusting method can adopt a separated design through two measurement modes of photoelectric transmission and reflection, and data acquired by the measurement sensor probe can be transmitted to the adjusting device in a wired or wireless mode, or the measurement sensor probe can be integrated on a glasses type device, such as glasses legs.

Heart rate: the blood pressure pulse wave is obtained or the blood oxygen volume wave is obtained, and the electrocardiogram wave acquired by the electrocardio electrode sensor can be obtained through calculation. The corresponding sensor and the adjusting device applying the biological rhythm self-adaptive adjusting method can adopt a separated design, and data collected by the sensor can be transmitted to the adjusting device in a wired or wireless mode, or the sensor can be integrated on a glasses type device, such as glasses legs.

Pulse wave: pulse wave waveform data can be obtained during blood pressure measurements and blood oximetry.

Blood pressure: the blood pressure estimation value can be obtained through measurement of a cuff type blood pressure meter or through calculation of pulse waves and electrocardio parameters. For example, the measurement result of the cuff type blood pressure meter is sent to the adjusting device for processing in a wired or wireless communication mode, or the pulse wave sensor is selected and integrated on the adjusting device, such as a temple.

Electroencephalogram parameters: the brain electrical parameters are sent to an adjusting device applying the biological rhythm self-adaptive adjusting method in a wired or wireless mode; the collecting electrode sensor can also be integrated on the glasses type device, and particularly, the collecting electrode sensor can be integrated on the glasses legs, contacting with the skin, of the two sides of the glasses type device and the forehead, such as the skin part close to the center of the eyebrow in the middle of the glasses frame or the nose support.

And S130, controlling a rhythm regulation component in real time at least according to the user characteristic information and the physiological parameters so as to enable the rhythm regulation component to act on the user.

In some possible embodiments, as shown in fig. 1 and fig. 2, the step S130 of controlling the rhythm regulation component in real time according to at least the user characteristic information and the physiological parameter specifically includes:

and S131, controlling a rhythm regulation component in real time according to the user characteristic information and the physiological parameters so as to enable the rhythm regulation component to act on the user.

In some possible embodiments, the rhythm adjusting component is controlled in real time through preset adjusting logic based on the user characteristic information and the physiological parameters acquired in real time.

In some feasible embodiments, the user characteristic information and the physiological parameters acquired in real time are transmitted to an intelligent algorithm program for analysis, and the intelligent algorithm program carries out real-time analysis processing on the data to obtain a decision result, so that the control parameters can be output to the rhythm regulation component in real time according to the decision result, and the rhythm regulation component can be controlled in real time.

In some possible embodiments, step S131 controls the rhythm regulation component in real time according to the user characteristic information and the physiological parameter, specifically:

and controlling a rhythm adjusting component in real time according to the user characteristic information and the physiological parameters through the trained neural network model.

In some possible embodiments, the neural network model is trained using training samples based on an existing neural network model; illustratively, the training samples include user characteristic information, physiological parameters, and control parameters of the desired rhythm adjustment components. After the training of the neural network model is finished, the output control parameters can be very close to expected values based on the input user characteristic information and the real-time acquired physiological parameters, so that the rhythm regulation component is comprehensively controlled by the user characteristic information and the physiological parameters of the user in real time, and the rhythm regulation component acts on the user.

In some possible embodiments, as shown in fig. 3, the rhythm regulation component is controlled in real time in step S130, specifically including at least one of step S101-step S104.

S101, controlling the rhythm regulation assembly to adjust the numerical value, the distribution range, the inflation and deflation sequence, the inflation and deflation time and/or the pressure conversion frequency of the output pressure in real time; thereby exerting pressure on the user, realizing the function of massaging the user according to the user characteristic information and the physiological parameters of the user so as to adjust the biological rhythm of the user.

For example, the inflatable single-cavity or multi-cavity air bag device wrapped on the trunk and/or the head of the four limbs of the human body is controlled to provide pressure stimulation for the user, and control parameters such as pressure value, pressure distribution range, inflation and deflation sequence and time, pressure conversion frequency and the like output to the air bag device can be specifically adjusted.

S102, controlling the rhythm regulation component to regulate the intensity, direction, action time and/or electrical stimulation frequency of output current in real time; thereby applying electric stimulation to the user, and realizing the function of regulating the biological rhythm of the user by electrically stimulating the user according to the user characteristic information and the physiological parameters of the user.

For example, electrical stimulation can be generated by contacting the surface of a human body with various conductive materials, and control parameters such as the current intensity output to the conductive materials, the position sequence and time of the electrodes, the stimulation frequency and the like can be specifically adjusted.

Step S103, controlling the rhythm regulation component to adjust the wavelength, the flicker frequency, the light intensity, the light and shade sequence and/or the light and shade frequency of the output light in real time; thereby applying light stimulation to the user, and realizing the function of performing light stimulation on the user according to the user characteristic information and the physiological parameters of the user so as to adjust the biological rhythm of the user.

Illustratively, the light stimulus to the eye can be generated by a single-wavelength or multi-wavelength light source and a combination thereof on the wearable glasses-type device, and specifically, the control parameters such as light color selection, light color sequence, light color combination, light intensity, flashing frequency, duration and the like output to the light source can be adjusted.

Step S104, controlling the rhythm regulation component to adjust the type, volume, frequency, duration and/or combination mode of various sounds of the output sound in real time; thereby applying sound stimulation to the user, and realizing the function of performing sound stimulation on the user according to the user characteristic information and the physiological parameters of the user so as to adjust the biological rhythm of the user.

For example, the sound output unit on the wearable glasses type device generates sound stimulation to the ear canal, and specifically, the sound size, the sound frequency and the combination of the frequencies, the selection of the sound, the combination of the sounds and other control parameters of the sound output unit can be adjusted.

The rhythm regulation component outputs sound stimulation, light color stimulation, electrical stimulation and/or pressure stimulation to act on a user, collects, analyzes and feeds back stimulation to the circadian rhythm in a non-invasive mode, and adjusts control parameters of the rhythm regulation component in real time, so that the rhythm regulation component adjusts and outputs frequency, intensity, time, size and the like of various stimulation modes in real time, intervenes, induces or strengthens a circadian rhythm regulation mechanism of the human body through external stimulation to the human body, achieves a regulation effect of the biological rhythm, and finally enables the biological rhythm of the user to reach an optimal state.

In some possible embodiments, as shown in fig. 4, the adaptive biorhythm adjusting method further includes the steps of:

and step S140, acquiring environment information.

In some possible embodiments, the environmental information is acquired before the physiological parameters of the user are acquired in real time in step S120. Illustratively, the environmental information may be acquired before step S110, or may be acquired after step S110.

In some possible embodiments, the adjusting device applying the adaptive biorhythm adjusting method may directly acquire the environmental information, and in other possible embodiments, the adjusting device may acquire the environmental information through a smart terminal or a smart detecting instrument.

In some possible embodiments, the adjusting device applying the biorhythm adaptive adjusting method may be directly networked to communicate with the environment information server to obtain the environment information of the region where the user is located from the environment information server; in other possible embodiments, the adjusting device applying the adaptive biorhythm adjusting method may communicate with an intelligent terminal, and the intelligent terminal may obtain the environmental information of the region where the user is located from the environmental information server, so that the adjusting device may obtain the environmental information of the region where the user is located from the environmental information server through the intelligent terminal.

In some possible embodiments, the environmental information includes at least one of a region, a temperature, a humidity, a weather, a sunrise time, a sunset time, and the like.

The region may represent a country or a region where the user is located, and may specifically be positioning information of the adjustment device or the intelligent terminal; the temperature and the humidity of the environment where the user is located can be obtained from an environment information server according to the positioning information, and can also be obtained from an intelligent terminal or an intelligent detection instrument which can be communicated with the adjusting device according to the positioning information; the weather, the sunrise time and the sunset time can be acquired from the environment information server according to the positioning information, for example, the wind, the rain, the snow, the haze and the like in a certain area.

In the foregoing step S130, the real-time controlling a rhythm regulation component according to at least the user characteristic information and the physiological parameter specifically includes:

and S132, controlling a rhythm adjusting component in real time according to the user characteristic information, the environmental information and the physiological parameters.

Constants or variables in environmental information such as region, temperature, humidity, weather, sunrise time, sunset time, etc. are also important for adjustment of control parameters for controlling the rhythm regulation module. Such as: people in all countries and all regions have their own living habits and the incidence rate of certain diseases; for another example, sunrise time, sunset time, and sleep are highly related. By unifying the factor of the environmental information into the biological rhythm self-adaptive adjusting method, the output of the rhythm adjusting component can be controlled more specifically, so that the rhythm adjusting component acts on a user, and the biological rhythm adjusting effect is better.

Illustratively, if the environmental information indicates that the air temperature is low and haze occurs, user characteristic information of the user, such as an existing disease, is combined; it is necessary to relatively decrease the intensity and duration of the output stimuli of the rhythm regulation element, etc.

In some feasible embodiments, the user characteristic information, the environment information and the physiological parameters acquired in real time are transmitted to the intelligent algorithm program for analysis, and the intelligent algorithm program performs real-time analysis processing on the data to obtain a decision result, so that the control parameters can be output to the rhythm regulation component in real time according to the decision result, and the rhythm regulation component can be controlled in real time.

In some possible embodiments, step S132 controls the rhythm regulation component in real time according to the user characteristic information, the environmental information, and the physiological parameter, specifically:

and controlling a rhythm adjusting component in real time according to the user characteristic information, the environmental information and the physiological parameters through the trained neural network model.

In some possible embodiments, the neural network model is trained using training samples based on an existing neural network model; illustratively, the training samples include user characteristic information, environmental information, physiological parameters, and control parameters of the desired rhythm adjustment components. After the training of the neural network model is finished, the output control parameters can be very close to expected values based on the input user characteristic information, the input environmental information and the real-time acquired physiological parameters, so that the rhythm regulation component is controlled in real time by integrating the user characteristic information, the environmental information and the physiological parameters of the user, and the rhythm regulation component acts on the user.

The embodiment of the utility model provides a biological rhythm self-adaptation adjusting method, through the environmental information that user characteristic information and/or user that acquire located to and the real-time physiological parameter real-time control rhythm regulation subassembly 300 of the user who acquires, so that rhythm regulation subassembly 300 acts on the user, with the individual sign state of user and/or the environmental factor that the user located as the basis that biological rhythm was adjusted, therefore biological rhythm self-adaptation adjusting has more pertinence, and the regulating effect is better.

Example two

Fig. 5 and 6 are schematic diagrams showing the structure of a biological rhythm adaptive adjusting device.

The biological rhythm self-adaptive adjusting device comprises a control component 100, a parameter acquisition component 200 and a rhythm adjusting component 300, wherein the parameter acquisition component 200 and the rhythm adjusting component 300 are in communication connection with the control component 100.

The parameter collecting assembly 200 is used for collecting the physiological parameters of the user in real time and transmitting the collected physiological parameters to the control assembly 100 in real time.

In some possible embodiments, the parameter collecting component 200 collects the physiological parameters of the user in real time, which specifically includes: at least one of the electrocardio-parameters, the body temperature, the skin humidity, the skin impedance, the respiration rate, the blood oxygen saturation, the heart rate, the pulse wave, the blood pressure and the electroencephalogram parameters of the user is acquired in real time.

In some possible embodiments, the parameter collecting assembly 200 includes at least one of an electrocardiograph unit for obtaining electrocardiographic parameters of a user, a body temperature unit for obtaining body temperature of the user, a humidity unit for obtaining skin humidity of the user, an impedance unit for obtaining skin impedance of the user, a respiration unit for obtaining respiration rate of the user, a blood oxygen unit for obtaining blood oxygen saturation of the user, a heart rate unit for obtaining heart rate of the user, a pulse wave unit for obtaining pulse waves of the user, a blood pressure unit for obtaining blood pressure of the user, and an electroencephalograph unit for obtaining electroencephalogram parameters of the user. The units in the parameter acquisition assembly 200 acquire physiological parameters of the user in a non-invasive manner.

In some possible embodiments, the ecg unit, the body temperature unit, the humidity unit, the impedance unit, the respiration unit, the blood oxygen unit, the heart rate unit, the pulse wave unit, the blood pressure unit, and/or the eeg unit are in communication with the control component 100 in a wired or wireless manner.

In some possible embodiments, the physiological parameter navigation adjusting device is provided with at least some units of the parameter collecting component 200, for example, the parameter collecting component 200 is disposed on the body of the mirror-frame type physiological parameter navigation adjusting device, so that the control component 100 can obtain the physiological parameters of the user in real time through the parameter collecting component 200; in other possible embodiments, the control assembly 100 may be communicatively connected to an external unit that collects the physiological parameters of the user in real time, so that the physiological parameters of the user can be obtained in real time by the external unit.

In some possible embodiments, the acquisition of the corresponding physiological parameter of the user by each unit in the parameter acquisition assembly 200 can be specifically obtained as follows:

electrocardio parameters: the sensor electrodes are used for collecting the signals from the body surface of a human body, and the sensor electrodes can be positioned in an external parameter collecting assembly 200 or a self-contained parameter collecting assembly 200. In this embodiment, the electrocardiograph unit may include the sensor electrode.

Body temperature: the temperature sensors may also be integrated on a glasses type device, such as the temple 620, by collecting on the skin surface through temperature sensors. In this embodiment, the body temperature unit includes the temperature sensor.

Skin moisture: the moisture sensors may be integrated on a glasses-type device, such as the temple 620, by collecting on the skin surface through the moisture sensors. In the present embodiment, the humidity unit includes the humidity sensor.

Skin impedance: the skin impedance values are measured on the skin surface by metal electrode sensors, which may also be integrated into a glasses-type device, such as the temple 620. In the present embodiment, the impedance unit includes the metal electrode sensor.

Breathing rate: the electrode or the respiration sensor can be positioned on a parameter acquisition component 200 connected with the outside of the electronic device; an estimated value of the respiration rate may also be calculated by filtering and analyzing the electrocardiographic data and the blood oxygen data, and an exemplary sensor for obtaining the blood oxygen data may be integrated into a glasses type device, such as the temple 620, by way of blood oxygen data analysis and estimation. In this embodiment, the respiration unit includes the sensor for acquiring blood oxygen data.

Oxygen saturation of blood: the measurement sensor probe and the biological rhythm self-adaptive adjusting device can adopt a separated design through two measurement modes of photoelectric transmission and reflection, data collected by the measurement sensor probe can be transmitted to the electronic device in a wired or wireless mode, or the measurement sensor probe can be integrated on a glasses type device, such as a glasses leg 620. In this embodiment, the blood oxygenation unit includes the measurement sensor probe.

Heart rate: the blood pressure pulse wave is obtained or the blood oxygen volume wave is obtained, and the electrocardiogram wave acquired by the electrocardio electrode sensor can be obtained through calculation. The corresponding sensor and the adaptive biorhythm regulator may be designed separately, and the data collected by the sensor may be transmitted to the electronic device in a wired or wireless manner, or the sensor may be integrated into a glasses type device, such as the glasses legs 620. In this embodiment, the heart rate unit includes a photosensor for acquiring the oximetry volume waveform.

Pulse wave: pulse wave waveform data can be obtained during blood pressure measurements and blood oximetry. In the present embodiment, the pulse wave unit includes sensors for blood pressure measurement and blood oxygen measurement.

Blood pressure: the blood pressure estimation value can be obtained through measurement of a cuff type blood pressure meter or through calculation of pulse waves and electrocardio parameters. Illustratively, the measurement result of the cuff type blood pressure meter is sent to the electronic device for processing in a wired or wireless communication mode, or the pulse wave sensor is selected and integrated on the electronic device, such as the temple 620. In the present embodiment, the blood pressure unit includes a pulse wave sensor.

Electroencephalogram parameters: the brain electrical parameters are sent to a biological rhythm self-adaptive adjusting device in a wired or wireless mode; the collecting electrode sensor may be integrated into a glasses type device, and particularly, the collecting electrode sensor may be integrated into the glasses type device at both sides of the glasses type device, on the temple 620 contacting with the skin, and at the forehead, such as the skin part near the center of the glasses frame 610 or the nose support. In the embodiment, the electroencephalogram unit includes the acquisition electrode sensor.

As shown in fig. 7, the control assembly 100 includes a memory 110 and a processor 120, the memory 110 being used to store program instructions; if the processor 120 executes the program instructions, the aforementioned biorhythm adaptive adjustment method is implemented.

In some possible embodiments, the biorhythm adaptive adjusting device may communicate with the smart terminal 10, such as a mobile phone, in a wired or wireless manner, so that the user characteristic information of the user may be obtained through the communication component 400 of the adjusting device.

In some possible embodiments, the circadian rhythm adaptive control apparatus further includes a communication component 400 connected to the control component 100, wherein the communication component 400 is configured to transmit the user characteristic information of the user acquired from the smart terminal 10 to the control component 100. Illustratively, the communication assembly 400 includes a bluetooth chip.

In other possible embodiments, the adaptive circadian rhythm control apparatus further includes an interactive component 500 connected to the control component 100, wherein the interactive component 500 is configured to acquire user characteristic information of the user and transmit the acquired user characteristic information to the control component 100. Therefore, the user characteristic information of the user can be obtained through the interactive component 500 of the self-adaptive biological rhythm adjusting device, such as a touch screen, a voice input module and the like.

In some possible embodiments, after the user sets the user feature information at a certain time, the user feature information is saved to the memory 110; the next time the user uses the biorhythm adaptive adjustment device, the processor 120 acquires the user characteristic information of the user from the memory 110.

In some possible embodiments, the user characteristic information includes at least one of age, gender, occupation, lifestyle habit, disease, medication, diet, sleep, and the like of the user. User characteristic information can embody user's sign state, the embodiment of the utility model provides a also as the foundation that follow-up biorhythm adjusted with user's user characteristic information. For example, user characteristic information set by a certain user includes age of 60 or more, chronic disease, dreaminess, use of a certain drowsy drug, and/or less than 6 hours of sleep, etc., which are then applied and valued in subsequently controlling the rhythm regulation member 300 so that the rhythm regulation member 300 acts on the user.

In some possible embodiments, the processor 120 of the control unit 100 is configured to control the rhythm adjustment unit 300 in real time according to the user characteristic information and the physiological parameter, so that the rhythm adjustment unit 300 acts on the user.

In some possible embodiments, the memory 110 is a memory 110 storing preset adjustment logic; the processor 120 retrieves the preset adjustment logic from the memory 110, and controls the rhythm adjustment module 300 in real time based on the user characteristic information and the real-time retrieved physiological parameters.

In other possible embodiments, the circadian rhythm adaptive adjustment device further acquires environmental information to control the rhythm adjustment component 300 in real time according to the user characteristic information and/or the environmental information, and the physiological parameter.

In some possible embodiments, the control component 100 is used to control the rhythm regulation component 300 in real time according to the environmental information and the physiological parameters acquired from the parameter acquisition component 200, so that the rhythm regulation component 300 acts on the user. In other possible embodiments, the control component 100 is used to control the rhythm regulation component 300 in real time according to the user characteristic information and the physiological parameters acquired from the parameter acquisition component 200, so that the rhythm regulation component 300 acts on the user. In other possible embodiments, the control component 100 is configured to control the rhythm adjustment component 300 in real time according to the environmental information and the user characteristic information, and the physiological parameters acquired from the parameter acquisition component 200, so that the rhythm adjustment component 300 acts on the user.

In some possible embodiments, the biorhythm adaptive adjusting device itself includes GPS, temperature sensor, etc. and can directly obtain the environment information, and in other possible embodiments, the biorhythm adaptive adjusting device can obtain the environment information from the smart terminal 10 or the smart detection instrument through the communication component 400.

In some possible embodiments, the adaptive biorhythm adjusting device may be directly networked through the communication component 400 to communicate with the environment information server to obtain the environment information of the region where the user is located from the environment information server; in other possible embodiments, the biorhythm adaptive control device may communicate with the smart terminal 10, and the smart terminal 10 may acquire the environmental information of the region where the user is located from the environmental information server, so that the biorhythm adaptive control device may acquire the environmental information of the region where the user is located from the environmental information server through the smart terminal 10.

In some possible embodiments, the environmental information includes at least one of a region, a temperature, a humidity, a weather, a sunrise time, a sunset time, and the like.

The region may represent a country or a region where the user is located, and may specifically be positioning information of the adjustment device or the intelligent terminal 10; the temperature and humidity of the environment where the user is located can be obtained from an environment information server according to the positioning information, and can also be obtained from an intelligent terminal 10 or an intelligent detection instrument which can be communicated with the adjusting device according to the positioning information; the weather, the sunrise time and the sunset time can be acquired from the environment information server according to the positioning information, for example, the wind, the rain, the snow, the haze and the like in a certain area.

In some possible embodiments, rhythm regulation component 300 includes: at least one of a gas pressure unit 310, an electrical stimulation unit 320, a light emitting unit 330, and a sound unit 340.

In some possible embodiments, the gas pressure unit 310, the electrical stimulation unit 320, the light emitting unit 330, and/or the sound unit 340 are communicatively connected with the control assembly 100 in a wired manner or a wireless manner.

In some possible embodiments, the gas pressure unit 310 comprises an inflatable single or multi-chamber bladder that is wrapped around a predetermined portion of the body, such as a limb, torso, and/or head of the body. So that pressure stimulation of the head, eyes, upper limbs, waist, lower limbs and/or feet can be performed. The air bag can be designed into a single-cavity air bag or a multi-cavity air bag according to different stimulation parts, the pressure regulation of the air pump on different cavities or air bags can be realized by adjusting the numerical value, the distribution range, the inflation and deflation sequence, the inflation and deflation time and/or the pressure conversion frequency of output pressure, the stimulation of the parts with sequential massage and serialization is realized, and the regulation change of the biological rhythm of the human body is caused by the pressure stimulation on the human body and a sensory nervous system. For example, the multi-cavity air bag on the leg comprises four regions from top to bottom, the pressure control of each region is different, the inflation and deflation sequences are different, and the simulation of the massage process can be realized by different duration time, so that the human body reaches a relaxed state, and further the relaxation of the nervous system is caused.

In some possible embodiments, electrical stimulation unit 320 includes electrodes, for example including electrode clips for clipping onto the ear. By adopting a non-invasive mode, the electrodes are used for contacting the skin and outputting microcurrent stimulation.

In some possible embodiments, the sensory nervous system is stimulated by controlling the intensity of the stimulation current, the frequency and combination of frequencies, the stimulation time, etc., to cause a modulation change in the biological rhythm. In some feasible embodiments, according to the current heart rate and blood pressure state of the user, the existing disease condition is combined to form an electrical stimulation parameter, and the electrodes connected to the muscle groups of the upper limbs or the lower limbs are controlled to send out current stimulation with certain intensity and frequency, so that the effects of relieving pain, improving muscle strength and the like are achieved.

In some possible embodiments, the electrode clips used for clipping on the ears can be used for stimulating the ear acupoints of the user, so as to achieve the purpose of regulating the biological rhythm.

In some possible embodiments, the light emitting unit 330 includes one light emitting element, or a plurality of light emitting elements of different wavelengths; the light emitting element emits light at a wavelength of 300nm to 3000 nm. The light intensity, the light color, the conversion frequency, the duration and the combination mode of the light source are controlled to stimulate the visual nerve so as to influence the biological rhythm. For example, when it is necessary to relax the nerves and reduce the blood pressure, the control parameters are output to control the light emitting unit 330 to emit orange light, and to control the light emitting intensity and the light and dark frequency thereof, so as to adjust the nervous system by stimulating the light of the vision, thereby achieving the effect of relaxing the user, and further reducing the blood pressure and stabilizing the heart rate.

In some possible embodiments, the sound unit 340 includes a speaker, and the stimulation of the sound can be performed by controlling the selection of the sound playing of the speaker, the size of the sound, the frequency of the sound, and the combination of the frequencies. The stimulation by sound causes the change of the auditory nervous system of the user to further influence the biological rhythm. For example, white noise is played according to the parameters to induce sleep, relaxing music is played to relax the nervous system, high-frequency music is played to promote arousal, and the like.

In some possible embodiments, as shown in fig. 6, the biorhythm adaptive adjusting device further includes a frame-shaped body 600, and the frame-shaped body 600 includes a frame 610 and a temple 620 connected to the frame 610.

The electro-stimulation unit 320 and/or the sound unit 340, and the control assembly 100 are positioned on the temples 620, and the light emitting unit 330 is positioned on the frame 610. In this embodiment, the electrical stimulation unit 320 includes an electrode clip for clipping on the ear, and the light emitting unit 330 includes one light emitting element or a plurality of light emitting elements (not shown) with different wavelengths; the light emitting element emits light at a wavelength of 300nm to 3000 nm.

In some possible embodiments, a body temperature unit, an impedance unit, and/or a blood oxygen unit are located on the temple 620. When a user wears the glasses type biological rhythm self-adaptive adjusting device, the body temperature unit, the impedance unit and/or the blood oxygen unit are abutted against the head of the user, so that the detection accuracy of the body temperature unit, the impedance unit and/or the blood oxygen unit can be ensured.

In some possible embodiments, the body temperature unit includes a temperature sensor, the impedance unit includes a skin impedance sensor, and the blood oxygen unit includes a photo-oximetry pulse sensor (not shown).

The embodiment of the utility model provides a biological rhythm self-adaptation adjusting device, through the environmental information who acquires user's subscriber feature information and/or user and locate to and the real-time physiological parameter real time control rhythm regulation subassembly 300 who acquires user, so that rhythm regulation subassembly 300 acts on the user, with the individual sign state of user and/or the environmental factor that the user located as the basis that biological rhythm was adjusted, therefore biological rhythm self-adaptation adjusting has more pertinence, and the regulating effect is better.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims (10)

1. A biological rhythm adaptive adjusting device, characterized in that: the device comprises a parameter acquisition component, a control component and a rhythm regulation component, wherein the parameter acquisition component and the rhythm regulation component are in communication connection with the control component;

the parameter acquisition assembly is used for acquiring physiological parameters of a user in real time and transmitting the acquired physiological parameters to the control assembly in real time;

the biological rhythm self-adaptive adjusting device also comprises a communication component connected with the control component, and the communication component is used for transmitting the environment information and/or the user characteristic information of the user acquired from the intelligent terminal to the control component;

the control component is used for controlling the rhythm regulating component in real time according to the environmental information and/or the user characteristic information and the physiological parameters acquired from the parameter acquisition component, so that the rhythm regulating component acts on a user.

2. The adaptive biorhythm adjusting device according to claim 1, wherein: the system comprises a control assembly and an interaction assembly connected with the control assembly, wherein the interaction assembly is used for acquiring user characteristic information of a user and transmitting the acquired user characteristic information to the control assembly.

3. The biorhythm adaptive adjustment apparatus as claimed in claim 1 or 2, wherein: the parameter acquisition assembly comprises an electrocardio unit for acquiring electrocardio parameters of a user, a body temperature unit for acquiring the body temperature of the user, a humidity unit for acquiring the skin humidity of the user, an impedance unit for acquiring the skin impedance of the user, a breathing unit for acquiring the breathing rate of the user, a blood oxygen unit for acquiring the blood oxygen saturation of the user, a heart rate unit for acquiring the heart rate of the user, a pulse wave unit for acquiring the pulse wave of the user, a blood pressure unit for acquiring the blood pressure of the user and at least one of an electroencephalogram unit for acquiring electroencephalogram parameters of the user.

4. The adaptive biorhythm adjusting device according to claim 3, wherein: the electrocardio unit, the body temperature unit, the humidity unit, the impedance unit, the respiration unit, the blood oxygen unit, the heart rate unit, the pulse wave unit, the blood pressure unit and/or the electroencephalogram unit are in communication connection with the control component in a wired mode or a wireless mode.

5. The adaptive biorhythm adjusting device according to claim 3, wherein: the rhythm adjustment assembly includes: at least one of a gas pressure unit, an electrical stimulation unit, a light emitting unit and a sound unit.

6. The adaptive biorhythm adjusting device according to claim 5, wherein: the gas pressure unit, the electrical stimulation unit, the light-emitting unit and/or the sound unit are in communication connection with the control assembly in a wired mode or a wireless mode.

7. The adaptive biorhythm adjusting device according to claim 5, wherein:

the gas pressure unit comprises an inflatable single-cavity airbag or a multi-cavity airbag which is wrapped at a preset part of a human body;

the electrical stimulation unit comprises an electrode clip for clipping on an ear;

the light emitting unit comprises one light emitting element or a plurality of light emitting elements with different wavelengths; the light-emitting element emits light with a wavelength of 300nm to 3000 nm.

8. The adaptive biorhythm adjusting device according to claim 5, wherein: the glasses frame comprises a glasses frame body and glasses legs connected to the glasses frame body;

the electric stimulation unit and/or the sound unit and the control component are positioned on the glasses legs, and the light-emitting unit is positioned on the glasses frame.

9. The adaptive biorhythm adjusting device according to claim 8, wherein: the body temperature unit, the impedance unit and/or the blood oxygen unit are/is located on the glasses legs.

10. The biorhythm adaptive adjustment device according to claim 9, wherein: the body temperature unit includes temperature sensor, the impedance unit includes skin impedance sensor, blood oxygen unit includes photoelectricity blood oxygen pulse sensor.