CN109124603B - Human health monitoring method and device, wearable device and storage medium - Google Patents

Abstract

The invention discloses a human health monitoring method and a device thereof, wearable equipment and a computer readable storage medium, wherein the human health monitoring method can be applied to the wearable equipment, and comprises the following steps: acquiring human health reference information with duration, wherein the human health reference information at least comprises at least one of human body surface temperature information, pulse information and sounding information; determining abnormal human health conditions according to the human health reference information; and generating a mode control signal for the wearable device according to the abnormal condition of the human health so as to enable the wearable device to work in a corresponding mode. The human health monitoring method can improve the convenience and timeliness of human health monitoring.

Description

Human health monitoring method and device, wearable device and storage medium

Technical Field

The invention relates to the technical field of information processing, in particular to a human health monitoring method and device, wearable equipment and a computer readable storage medium.

Background

With economic development and social progress, people have higher and higher requirements on life quality, stronger and stronger health consciousness, and increasingly prominent daily health care and health monitoring requirements.

Currently, apparatuses for human health monitoring are usually specialized medical monitoring apparatuses, such as various monitoring apparatuses commonly used in hospitals for organs such as heart, brain, etc. However, these devices are not only too expensive for daily health monitoring of individuals, but also complicated to operate and are not suitable for the daily needs of people. Therefore, how to improve the convenience of daily human health monitoring is a problem to be solved.

Disclosure of Invention

The invention provides a human health monitoring method and a device thereof, wearable equipment and a computer readable storage medium, which aim to solve the defects in the related art.

According to a first aspect of the embodiments of the present invention, there is provided a human health monitoring method applied to a wearable device, the method including:

acquiring human health reference information with duration, wherein the human health reference information at least comprises at least one of human body surface temperature information, pulse information and sounding information;

determining abnormal human health conditions according to the human health reference information;

and generating a mode control signal for the wearable device according to the abnormal condition of the human health so as to enable the wearable device to work in a corresponding mode.

Optionally, the determining the abnormal human health condition according to the reference human health information includes:

when the average temperature of the body surface of the human body within the duration is less than the first temperature, determining that the human body is in a temperature loss state;

when the number of sneezing determined according to the sounding information in the duration is larger than the first number and/or the number of coughing is larger than the second number, determining that the human body is in the initial cold state;

when the average temperature of the body surface of the human body in the duration is greater than the second temperature and the average pulse frequency in the duration is not greater than the first pulse frequency, determining that the human body is in a fever state;

and when the average pulse frequency in the duration is greater than the second pulse frequency or less than the third pulse frequency, determining that the human body is in a health threat state.

Optionally, the generating a mode control signal for the wearable device according to the abnormal condition of the human health to enable the wearable device to operate in a corresponding mode includes:

when the abnormal condition of the health of the human body is that the human body is in a temperature loss state or a cold initial state, generating a heating mode signal to control an infrared lamp on the wearable device to continuously emit light for a set time;

when the abnormal condition of the human health is that the human body is in a heating state or a health threat state, an alarm mode signal is generated to control the wearable equipment to send out alarm information.

Optionally, the generating a heating mode signal when the abnormal condition of the health of the human body is that the human body is in an unhealthy state or an early cold state includes:

when the abnormal condition of the human health is that a human body is in a temperature losing state or a cold initial state, a plurality of different heating signals are generated based on the acquired human arterial pressure corresponding to a plurality of different positions in the coverage area of the wearable device, each heating signal is used for respectively controlling the luminous intensity of each infrared lamp on the wearable device, and the luminous intensity of each infrared lamp is in inverse proportion to the pressure corresponding to the position of the infrared lamp.

Optionally, the generating a heating mode signal when the abnormal condition of the health of the human body is that the human body is in an unhealthy state or an early cold state includes:

when the abnormal condition of the human health is that a human body is in a temperature loss state or a cold initial state, determining the distance between each infrared lamp on the wearable device and the position of the human artery based on the acquired human artery pressure corresponding to a plurality of different positions in the coverage area of the wearable device;

and generating a plurality of different heating signals according to the distances, wherein each heating signal is used for respectively controlling the luminous intensity of each infrared lamp on the wearable equipment, and the luminous intensity of each infrared lamp is in direct proportion to the distance between the infrared lamp and the position of the artery of the human body.

Optionally, when the abnormal condition of the human health is that the human body is in an unhealthy state or an initial cold state, generating a heating mode signal, including;

when the abnormal condition of the human health is that the human body is in a temperature loss state, generating a plurality of different first heating signals based on the acquired human body arterial pressure corresponding to a plurality of different positions in the coverage area of the wearable equipment so as to control an infrared lamp in the wearable equipment to continuously emit light for a first time;

when the abnormal condition of the human health is that the human body is in an initial cold state, generating a plurality of different second heating signals based on the acquired human arterial pressure corresponding to a plurality of different positions in the coverage area of the wearable device so as to control the infrared lamp in the wearable device to continuously emit light for a second time length, wherein the second time length is longer than the first time length.

According to a second aspect of the embodiments of the present invention, there is provided a human health monitoring device applied to a wearable device, the device including:

the information acquisition unit is used for acquiring human health reference information with duration set, and the human health reference information at least comprises at least one of human body surface temperature information, pulse information and sounding information;

the health condition determining unit is used for determining the abnormal condition of the human health according to the human health reference information;

and the mode control signal generation unit is used for generating a mode control signal for the wearable device according to the abnormal condition of the human health so as to enable the wearable device to work in a corresponding mode.

According to a third aspect of embodiments of the present invention, there is provided a wearable device, comprising:

the flexible substrate is in a closed ring shape;

the flexible substrate is provided with an acquisition unit, a control chip and a power supply;

the acquisition unit is used for acquiring the body surface temperature of the human body, the arterial pressure of the human body and/or the sound emitted by the human body in real time;

the control chip is used for acquiring human body health reference information with a duration set time according to real-time acquisition of human body surface temperature, human body arterial pressure and/or sound emitted by a human body, determining human body health abnormal conditions according to the human body health reference information, and generating mode control signals for the wearable equipment according to the human body health abnormal conditions so as to enable the wearable equipment to work in a corresponding mode;

the power supply is used for providing working electric energy for the detection unit and the control chip.

Optionally, the detection unit includes a sound sensor, a plurality of temperature sensors, and a plurality of vibration sensors; the device also comprises an alarm element and a plurality of infrared lamps;

the sound sensor is used for collecting sound emitted by a human body in real time, the temperature sensor is used for collecting the temperature of the body surface of the human body in real time, and the vibration sensor is used for collecting the arterial pressure of the human body in real time;

the control chip, the power supply, the sound sensor and the alarm element are all arranged on the outer side of the flexible substrate;

the temperature sensors, the vibration sensors and the infrared lamps are alternately distributed on the inner side of the flexible substrate in an array manner;

the sound sensor, the alarm element, the temperature sensors, the vibration sensors and the infrared lamps are respectively connected with a control chip.

Optionally, the method further includes:

and the packaging layer covers the plurality of temperature sensors, the plurality of vibration sensors and the plurality of infrared lamps so as to package the plurality of temperature sensors, the plurality of vibration sensors and the plurality of infrared lamps on the flexible substrate.

According to a fourth aspect of embodiments of the present invention, there is provided a computer readable storage medium, having stored thereon a computer program which, when executed by a processor, performs the steps of any of the methods described above.

According to the technical scheme, the human health monitoring method can be applied to wearable equipment, abnormal conditions of human health can be found in time through the acquired human health reference information, the wearable equipment can work in a corresponding mode, and effects of reminding and early-stage prevention are achieved, so that convenience and timeliness of human health monitoring are improved.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.

FIG. 1 is a workflow diagram of a human health monitoring method provided according to an exemplary embodiment of the invention;

FIG. 2 is a schematic diagram of a wearable device detecting a human artery pressure in relation to a location of a human artery according to an exemplary embodiment of the invention;

FIG. 3 is a block diagram of a human health monitoring device provided in accordance with an exemplary embodiment of the present invention;

fig. 4 is a schematic structural diagram of a wearable device provided in accordance with an exemplary embodiment of the present invention;

fig. 5 is a schematic diagram of a cross-sectional structure of a wearable device worn on a wrist according to an exemplary embodiment of the invention.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present invention. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the invention, as detailed in the appended claims.

Aiming at the problem of poor convenience in daily human health monitoring, the embodiment of the invention provides a human health monitoring method which is applied to wearable equipment, and as shown in fig. 1, the method comprises the following steps:

step S10, acquiring human health reference information with duration, wherein the human health reference information at least comprises at least one of human body surface temperature information, heart rate information and sounding information;

step S20, determining abnormal human health conditions according to the human health reference information;

and step S30, generating a mode control signal for the wearable device according to the abnormal condition of the human health, so that the wearable device works in a corresponding mode.

Wearable equipment is a portable equipment that can directly wear on the person, and wearable equipment is not merely a hardware equipment, can also realize more functions through software support and data interaction, high in the clouds interaction etc.. Wearable devices are for example smart watches, smart bracelets, smart neck rings, smart foot rings and the like.

The human health reference information is related information for representing human body conditions, wherein the human body surface temperature can reflect whether the human body temperature is normal, the pulse is an important index for reflecting whether the parts of the human body, such as the heart, the heart blood vessel, the brain, and the like, are healthy, the sounding condition of the human body is also a factor for reflecting the human health state, for example, when people catch a cold or suffer from pneumonia and other diseases, the human health reference information can be used for judging the human health condition according to the sound, such as repeated coughing or sneezing and the like.

For the human health reference information, for example, the body surface temperature, pulse and sound information, etc., if the real-time data is used as the basis, the accuracy is poor, so the information with the duration set as the basis, for example, the average body surface temperature, the average pulse frequency, the cough frequency and the sneeze frequency within a period of time are used as the basis to determine whether the human body has abnormal health conditions.

Generating a corresponding mode control signal according to the determined abnormal condition of the human health, wherein the wearable device is in different working modes for different abnormal conditions of the human health, for example, when the abnormal condition of the human health is a slight abnormal condition of the human health, the wearable device can work in a prevention mode, for example, the wearable device can continuously heat the local part of the human body through a heating element on the wearable device; when the abnormal condition of the human health is a more serious abnormal condition (such as sudden heart disease or fever), the wearable device can work in an alarm mode, and the alarm mode is that the wearable device alarms through an alarm element on the wearable device.

According to the description, the human health monitoring method can be applied to wearable equipment, abnormal conditions of human health can be found in time through the obtained human health reference information, the wearable equipment can work in a corresponding mode, and effects of reminding and early-stage prevention are achieved, so that convenience and timeliness of human health monitoring are improved.

In an alternative embodiment, as shown in fig. 2, the determining the abnormal condition of the human health according to the reference information of the human health in step S20 includes:

step S21, when the average temperature of the human body surface within the duration is less than the first temperature, determining that the human body is in a temperature losing state;

step S22, when the number of sneezes determined according to the sounding information in the duration is larger than the first number and/or the number of coughs is larger than the second number, determining that the human body is in the initial cold state;

step S23, when the average temperature of the body surface of the human body in the duration is higher than the second temperature and the average pulse frequency in the duration is not higher than the first pulse frequency, determining that the human body is in a fever state;

and step S24, when the average pulse frequency in the duration is larger than the second pulse frequency speed or smaller than the third pulse frequency, determining that the human body is in a health threat state.

In this embodiment, the average body surface temperature, the average pulse frequency, the number of sneezes, and the number of coughs over the duration are used to determine whether or not there is a health abnormality or a specific health abnormality.

When the average temperature of the body surface of the human body is lower than the first temperature, the body surface temperature of the human body is lower, the human body can be in a cold environment, for example, the outdoor temperature in winter is lower or the indoor temperature in summer is lower, if the human body lasts for a long time in the cold environment, the body surface temperature can obviously drop, health problems such as cold and the like are easily caused, and particularly for people with weak physique, such as children, old people or pregnant women, the situation is considered as that the human body is in a temperature loss state.

When the number of sneezes in the duration is greater than the first number and/or the number of sneezes is greater than the second number, the number of coughs or sneezes is greater in a period of time, indicating that the human body has already developed initial cold symptoms, which is considered to be the initial cold state.

When the average temperature of the human body surface is higher than the second temperature, the fact that the temperature of the human body surface is higher in a period of time is indicated, the situation that the temperature of the human body surface is higher is probably caused by movement, in order to eliminate the situation that the temperature of the human body surface is increased caused by movement, the accuracy of judgment is improved, the average pulse frequency is further judged, if the average pulse frequency is higher than the first pulse frequency, the fact that the human body is possibly in a movement state is indicated, if the average pulse frequency is not higher than the first pulse frequency, the average temperature of the human body surface is higher, and the fact that the human body is in a fever state is determined.

When the average pulse frequency is higher than the second pulse frequency or lower than the third pulse frequency, it indicates that the pulse frequency is too fast or too slow, and the reason for the too fast or too slow pulse frequency may be caused by heart disease, cardiovascular disease, brain disease or other diseases, such as heart disease, heart failure, myocardial infarction, meningitis, cerebral hemorrhage, brain tumor, encephalitis, brain trauma, fever, shock, anemia, hypoxia, hyperthyroidism, etc., which may be regarded as more serious diseases, and if not treated in time, it is likely to cause more serious consequences or even death, and the human body is determined to be in a health threat state.

The duration may be a fixed period of time, or a period of time set as needed, and the first temperature, the second temperature, the first pulse frequency, the second pulse frequency, and the third pulse frequency may be set according to a situation of a user using the wearable device, or data calculated by analyzing collected historical data of the user, and the first number of times and the second number of times may be preset empirical values.

Further, the generating a mode control signal for the wearable device according to the abnormal condition of the human health in step S30 above, so that the wearable device operates in a corresponding mode, includes:

step S31, when the abnormal condition of the human health is that the human body is in the state of losing temperature or the state of the early cold, generating a heating mode signal to control the infrared lamp on the wearable device to continuously emit light for a set time;

and step S32, when the abnormal condition of the human health is that the human body is in a heating state or a health threat state, generating an alarm mode signal to control the wearable equipment to send out alarm information.

In this embodiment, when judging that the human body is in the state of losing temperature or the initial state of a cold, wearable equipment works under the prevention mode, and the infrared lamp on wearable equipment lasts luminous the settlement time this moment, and the infrared lamp is luminous can heat and last the certain time to the human body region of luminous light coverage, helps promoting human body temperature, plays the effect of prevention cold or other healthy diseases.

When the human body is in a heating state or a health threat state, the health problem is possibly serious, the wearable device works in an alarm mode, the wearable device gives an alarm to play a role in timely reminding, a user using the wearable device or related personnel (such as family members of the user) are reminded to take treatment measures in time, and the condition that the illness state is worsened or the condition is serious due to untimely treatment is prevented from happening.

The specific method for generating the heating mode signal may include two ways, which are described below:

the first method comprises the following steps: when the abnormal condition of the human health is that a human body is in a temperature losing state or a cold initial state, a plurality of different heating signals are generated based on the acquired human arterial pressure corresponding to a plurality of different positions in the coverage area of the wearable device, each heating signal is used for respectively controlling the luminous intensity of each infrared lamp on the wearable device, and the luminous intensity of each infrared lamp is inversely proportional to the magnitude of the pressure value corresponding to the position of the infrared lamp.

The second method comprises the following steps: when the abnormal condition of the human health is that a human body is in a temperature loss state or a cold initial state, determining the distance between each infrared lamp on the wearable device and the position of the human artery based on the acquired human artery pressure corresponding to a plurality of different positions in the coverage area of the wearable device;

and generating a plurality of different heating signals according to the distances, wherein each heating signal is used for respectively controlling the luminous intensity of each infrared lamp on the wearable equipment, and the luminous intensity of each infrared lamp is in direct proportion to the distance between the infrared lamp and the position of the artery of the human body.

Arteries are distributed on a human body, the arteries are paths through which blood of the human body flows, when the blood enters the arteries, the pressure of the arteries is increased, the pipe diameter is expanded, the arteries at a shallow part of the body surface can feel the expansion, namely the so-called pulse, namely the artery pulsation, and the pulse frequency is the pulse rate.

The coverage area of the wearable device refers to the area of the human body which can be covered by the wearable device, and the position of the artery in the area is the position of the artery in the human body.

The wearable device can be provided with a plurality of vibration sensors and a plurality of infrared lamps, and the plurality of vibration sensors and the plurality of infrared lamps can be evenly distributed on the wearable device. After the user wears the wearable device, the vibration sensor can detect the pressure generated by the artery pulsation (pulse) of the human body corresponding to the position where the vibration sensor is located, and the pressure detected by each vibration sensor can be used as the human artery pressure corresponding to a plurality of different positions in the coverage area of the wearable device.

Because the positions of the vibration sensors are different from the position of the human artery, the pressure detected by the vibration sensors may be different, the pressure detected by the vibration sensors is related to the distance between the vibration sensors and the position of the human artery, and the larger the distance is, the smaller the detected pressure is, the smaller the distance is, and the larger the detected pressure is.

The user is after wearing wearable equipment, and each infrared lamp that sets up on it distributes on a plurality of position points in wearable equipment coverage area, and for example wearable equipment is the bracelet, and each infrared lamp evenly distributed is on the bracelet, and the bracelet area is behind human wrist, and each infrared lamp distributes on each position point around human wrist, and each infrared lamp is luminous can the production of heat.

In order to enable the heat generated by the light emission of each infrared lamp to be relatively concentrated at the position of the human artery so as to heat the blood flowing through the human artery, so as to increase the activity of white blood cells in blood and improve the immunity and the resistance of the human body, the light emitting direction of each infrared lamp can face to the direction of the position of the artery of the human body, the distances between the infrared lamps and the position of the human artery are usually different, the larger the distance between the infrared lamps and the position of the human artery is, the smaller the heat generated by the infrared lamps at the position of the human artery is, in order to ensure that the heat generated by the infrared lamps at the position of the action is approximately the same, the magnitude of the luminous intensity of each infrared lamp is controlled according to the distance between the infrared lamp and the position of the human artery, the larger the distance between the infrared lamp and the position of the human artery is, the larger the luminous intensity is, and the smaller the distance between the infrared lamp and the position of the human artery is, the smaller the luminous intensity is.

The luminous intensity of the infrared lamp is controlled by a heating signal, which may be an electrical signal (current signal or voltage signal) for controlling the infrared lamp to emit light, wherein the larger the current or voltage, the larger the luminous intensity of the infrared lamp, and the smaller the current or voltage, the smaller the luminous intensity of the infrared lamp.

The infrared lamp and the vibration sensor can be arranged in a close mode, the position of the vibration sensor can be regarded as the position of the infrared lamp, the pressure of the vibration sensor is inversely proportional to the distance between the pressure of the vibration sensor and the position of the human artery, therefore, the light emitting intensity of each infrared lamp is inversely proportional to the pressure detected by the vibration sensor (namely, the pressure corresponding to the position of the infrared lamp), namely, the larger the pressure detected by the vibration sensor corresponding to the position of the infrared lamp is, the smaller the light emitting intensity of the infrared lamp is, the smaller the pressure detected by the vibration sensor corresponding to the position of the infrared lamp is, and the larger the light emitting intensity of the infrared lamp is.

The heating signals are directly determined according to the pressure detected by the vibration sensors at different positions, that is, the heating signals corresponding to the infrared lamps are generated based on the acquired human artery pressure corresponding to a plurality of different positions in the coverage area of the wearable device.

In order to more accurately determine the intensity of the light emitted by each infrared lamp, the distance between the corresponding infrared lamp and the position of the artery of the human body is further determined according to the pressure detected by the vibration sensor, specifically, a mapping relation table between the actually detected pressure and the distance can be established according to a large amount of historical data of the actually detected pressure and the distance, when the distance is applied, the corresponding distance is found out from the mapping relation table according to the actually detected pressure, the distance is in direct proportion to the intensity of the light emitted by the infrared lamp, namely, the greater the distance is, the greater the intensity of the light emitted by the infrared lamp is, and the smaller the distance is.

Alternatively, the distance between each infrared lamp and the artery of the human body can be calculated according to a formula, for example, as shown in fig. 2, the wearable device is in a ring shape, 8 vibration sensors are arranged on the wearable device, and the Q is₁-Q₈The position of each vibration sensor is shown, and the position of each vibration sensor can also be regarded as the position of each infrared lamp, Q₀The point represents the position of the human artery after the wearable device is worn on the human body, and the pressure detected by each vibration sensor is P₁-P₈The distance between the position of each vibration sensor and the position of the human artery is L₁-L₈Each distance L can be calculated according to the following formula₁-L₈：

P_n＝P₀*L_m ²，cosθ_n＝(L_m ²+L_m+1 ²-L_an ²)/2；θ₁+θ₂+....+θ_n＝360。

In the above three formulas, the value of n is a positive integer, the maximum value of n is the total number of the vibration sensors, the value of m is a positive integer, the maximum value of n is the total number of the vibration sensors minus 1, for example, there are 8 vibration sensors, and the values of n and m may be: 1. 2, 3, 4, 5, 6, 7 and 8; when m is 8, L_m+1＝L₉At this time, set L₉＝L₁。

L_anIndicating the distance between the positions of two adjacent vibration sensors, e.g. L_a1Is shown at Q₁Vibration sensor of point and position Q₂Distance between vibration sensors of points, L_a2Is shown at Q₂Vibration sensor of point and position Q₃The distances between the vibration sensors of the points are analogized in turn, and it is noted that L_a2Is shown at Q₈Vibration sensor of point and position Q₁Distance between the vibration sensors of the dots.

P_nRepresenting the pressure detected by the vibration sensor, drawing a line segment, theta, between the vibration sensor and the location of the body artery_nAnd the included angle between two line segments of the positions of the two adjacent vibration sensors and the human artery is shown.

P_n、θ_nAnd L_anAll the known quantities are known quantities, and the known quantities are respectively substituted into the formula, and the distances L can be calculated by solving₁-L₈And the calculated distances can be regarded as the distances between the infrared lamps and the positions of the human artery.

In an alternative embodiment, the generating the heating mode signal when the abnormal condition of the human health is a state of losing temperature or an initial cold state in the step S31 includes:

step S311, when the abnormal condition of the human health is that the human body is in a temperature loss state, generating a plurality of different first heating signals based on the acquired human body artery pressures corresponding to a plurality of different positions in the coverage area of the wearable device so as to control an infrared lamp in the wearable device to continuously emit light for a first time;

step S311, when the abnormal condition of the human health is that the human body is in a temperature losing state, generating a plurality of different second heating signals based on the acquired human arterial pressure corresponding to a plurality of different positions in the coverage area of the wearable device so as to control the infrared lamp in the wearable device to continuously emit light for a second time length, wherein the second time length is longer than the first time length.

In the embodiment, when the human body is in the temperature loss state or the initial cold state, the light emitting duration of the infrared lamp is controlled to be different, the infrared lamp is used for continuously heating the human body for a period of time to help to keep the body temperature of the human body aiming at the condition that the human body is in the temperature loss state, and when the human body is in the initial cold state, the fact that the human body is infected by bacteria and viruses is indicated, under the condition, the infrared lamp is used for heating for a certain period of time and lasting for a long time, the body temperature of the human body can be improved, and the effect of preventing and treating cold can be achieved.

The first time period and the second time period may be set as needed, and are not limited herein.

An embodiment of the present invention further provides a human health monitoring device, which is applied to a wearable device, and as shown in fig. 3, the human health monitoring device 03 includes:

the information acquisition unit 301 is configured to acquire human health reference information with a duration set, where the human health reference information at least includes at least one of human body surface temperature information, pulse information, and utterance information;

a health condition determining unit 302, configured to determine a human health abnormal condition according to the human health reference information;

a mode control signal generating unit 303, configured to generate a mode control signal for the wearable device according to the abnormal human health condition, so that the wearable device operates in a corresponding mode.

Corresponding to the embodiment of the human health monitoring method, the human health monitoring device provided by the invention can be applied to wearable equipment, and the convenience and timeliness of human health monitoring are improved.

For the embodiment of the apparatus, the implementation process of the function and the action of each unit is specifically described in the implementation process of the corresponding step in the above method, and is not described herein again.

The above-described embodiments of the apparatus are merely illustrative, wherein the units described as separate parts may or may not be physically separate, may be located in one place, or may be distributed over a plurality of network units; the units may be combined into one unit, or further divided into a plurality of sub-units.

Through the description of the above embodiments, the apparatus of the present embodiment may be implemented by software, or by software plus necessary general hardware, and may also be implemented by hardware. Based on such understanding, the technical solution of the present invention or the portions contributing to the prior art may be embodied in the form of a software product, and as an example of a logical device, the device is formed by reading corresponding computer program instructions in a non-volatile memory into an internal memory for running through a processor in which a wearable device applying the device is located.

An embodiment of the present invention further provides a wearable device, including:

the flexible substrate is in a closed ring shape;

the flexible substrate is provided with an acquisition unit, a control chip and a power supply;

the acquisition unit is used for acquiring the body surface temperature, the pulse frequency and/or the sound emitted by the human body in real time;

the control chip is used for acquiring human body health reference information with duration set according to real-time acquisition of human body surface temperature, human body arterial pressure and/or sound emitted by a human body, determining human body health abnormal conditions according to the human body health reference information, and generating mode control signals for the wearable equipment according to the human body health abnormal conditions so that the wearable equipment works in corresponding modes.

The power supply is used for providing working electric energy for the detection unit and the control chip.

In the wearable device provided by the embodiment of the invention, the flexible substrate is in a closed ring shape, the acquisition unit, the control chip and the power supply are arranged on the flexible substrate, and the ring-shaped flexible substrate is used for being worn on a corresponding part of a human body, for example, the ring-shaped flexible substrate can be sleeved on a wrist, an ankle or a neck of the human body.

After the wearable equipment is worn by a human body, the human body surface temperature, the human body arterial pressure and/or the sound emitted by the human body are collected in real time through the collecting unit on the wearable equipment, particularly, the average human body surface temperature in the duration set can be obtained according to the human body surface temperature collected in real time, the average pulse frequency in the duration set can be obtained according to the human body arterial pressure collected in real time, and the sounding information in the duration set, such as the number of sneezing and the number of coughing, can be obtained according to the sound emitted by the human body collected in real time.

The control chip controls the wearable device to work in a corresponding mode according to the acquired health reference information, the power supply is used for providing required electric energy for the detection unit and the control chip, and the wearable device improves the convenience and timeliness of human health monitoring to a certain extent.

Fig. 4 is a schematic structural diagram of a wearable device according to an exemplary embodiment of the present invention, and referring to fig. 4, the wearable device includes:

the flexible substrate 10, the flexible substrate 10 is a closed ring;

a control chip 20, a power supply 30, an alarm element 41, a sound sensor 42, a plurality of temperature sensors 43, a plurality of vibration sensors 44 and a plurality of infrared lamps 45 are arranged on the flexible substrate 10;

the control chip 20, the power supply 30, the alarm element 41 and the sound sensor 42 are all arranged on the outer side of the flexible substrate 10;

the temperature sensors 43, the vibration sensors 44 and the infrared lamps 45 are alternately arranged in an array on the inner side of the flexible substrate 10.

An encapsulation layer 50 may also be included overlying the plurality of temperature sensors 43, the plurality of vibration sensors 44, and the plurality of infrared lamps 45 to encapsulate the plurality of temperature sensors 43, the plurality of vibration sensors 44, and the plurality of infrared lamps 45 on the flexible substrate 10.

The control chip 20, the power supply 30, the alarm element 41 and the sound sensor 42 disposed outside the flexible substrate 10 may also be packaged on the flexible substrate 10 by a packaging case 60.

In the wearable device, after the wearable device is worn on a human body, the inner side of the flexible substrate refers to a side of the flexible substrate close to the human body, for example, a side in contact with the skin of the human body, and the outer side of the flexible substrate refers to a side of the flexible substrate far away from the human body, namely, a side opposite to the inner side.

A plurality of temperature sensor, a plurality of vibration sensor and a plurality of infrared lamp evenly distributed on flexible substrate, and the distribution in turn, temperature sensor are used for the temperature of real-time collection human body surface, vibration sensor are used for real-time collection human artery pressure, and control chip can confirm human pulse frequency according to this pressure.

The infrared lamp is used for sending infrared light, and a plurality of temperature sensor, a plurality of vibration sensor and a plurality of infrared lamp set up the inboard at flexible substrate, help more accurate information collection.

The sound sensor is arranged on the outer side of the flexible substrate, and is beneficial to collecting sound emitted by a human body, the sound sensor, each vibration sensor and each temperature sensor send data collected in real time to the control chip, the control chip determines abnormal conditions of human health accordingly, controls whether the infrared lamp emits light and the duration of the light emission, and controls whether the alarm element gives an alarm, so that the wearable device works in a corresponding mode.

The alarm element can be a loudspeaker or a display screen, and the like, and the alarm information can be a sound or a character or symbol identifier, and the like, for example, the control chip controls the loudspeaker to emit the alarm sound or controls the display screen to display the alarm character or the alarm symbol identifier.

The above description of the manner in which the control chip controls the infrared lamp to emit light according to the reference information of human health is given, and is not repeated herein.

The wearable device is, for example, a smart bracelet, fig. 5 shows a schematic cross-sectional structure of the wearable device worn on a wrist of a human body, and referring to fig. 5, the wearable device 100 is worn on a wrist 200 of a human body, a position a of a human artery in a wrist area covered by the wearable device 100 is located, and a plurality of temperature sensors 43, a plurality of vibration sensors 44 and a plurality of infrared lamps 45 are uniformly distributed on the flexible substrate 10.

The vibration sensors 44 can detect the pressure of the positions corresponding to the positions of the human arteries, the infrared lamps 45 are uniformly distributed at each position point around the wrist 200, the control chip 20 can generate heating signals for the infrared lamps 45 and control the infrared lamps 45 to emit light, the light emitted by the infrared lamps faces the position A of the human artery, the light intensity of the infrared lamps 45 is in direct proportion to the distance between the light intensity of the infrared lamps 45 and the position A of the human artery, heat generated by the light emitted by the infrared lamps 45 can be concentrated at the position A of the human artery, blood flowing through the human artery is heated, the leukocyte activity in the blood can be increased, and the immunity and the resistance of the human body are improved.

The present invention also provides a computer readable storage medium, on which a computer program is stored, which when executed by a processor implements the steps of the human health monitoring method according to any of the above embodiments.

A machine-readable storage medium as referred to herein may be any electronic, magnetic, optical, or other physical storage device that can contain or store information such as executable instructions, data, and the like. For example, the machine-readable storage medium may be: a RAM (random Access Memory), a volatile Memory, a non-volatile Memory, a flash Memory, a storage drive (e.g., a hard drive), any type of storage disk (e.g., an optical disk, a dvd, etc.), or similar storage medium, or a combination thereof.

Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure disclosed herein. This invention is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.

Claims (8)

1. A human health monitoring device, characterized in that, be applied to wearable equipment, the device includes:

the information acquisition unit is used for acquiring human health reference information with duration set, and the human health reference information at least comprises at least one of human body surface temperature information, pulse information and sounding information;

the health condition determining unit is used for determining the abnormal condition of the human health according to the human health reference information; the abnormal condition of human health comprises a temperature loss state or an initial cold state;

the mode control signal generating unit is used for generating a mode control signal for the wearable device according to the abnormal condition of the human health so as to enable the wearable device to work in a corresponding mode, and comprises:

when the abnormal condition of the health of the human body is that the human body is in a temperature loss state or a cold initial state, generating a heating mode signal to control an infrared lamp on the wearable device to continuously emit light for a set time; when the abnormal condition of the human health is that a human body is in a temperature losing state or a cold initial state, a plurality of different heating signals are generated based on the acquired human arterial pressure corresponding to a plurality of different positions in the coverage area of the wearable device, each heating signal is used for respectively controlling the luminous intensity of each infrared lamp on the wearable device, and the luminous intensity of each infrared lamp is in inverse proportion to the pressure corresponding to the position of the infrared lamp.

2. The apparatus of claim 1, wherein the abnormal human health condition further comprises a fever state or a health threat state; the generating of the mode control signal to the wearable device according to the abnormal condition of the human health to enable the wearable device to work in a corresponding mode further comprises:

when the abnormal condition of the human health is that the human body is in a heating state or a health threat state, an alarm mode signal is generated to control the wearable equipment to send out alarm information.

3. The apparatus of claim 2, wherein generating a heating mode signal when the abnormal condition of the health of the human body is a state of losing temperature or an early cold condition comprises:

when the abnormal condition of the human health is that a human body is in a temperature loss state or a cold initial state, determining the distance between each infrared lamp on the wearable device and the position of the human artery based on the acquired human artery pressure corresponding to a plurality of different positions in the coverage area of the wearable device;

and generating a plurality of different heating signals according to the distances, wherein each heating signal is used for respectively controlling the luminous intensity of each infrared lamp on the wearable equipment, and the luminous intensity of each infrared lamp is in direct proportion to the distance between the infrared lamp and the position of the artery of the human body.

4. The apparatus of claim 1, wherein said generating a heating mode signal when the abnormal condition of the health of the human body is a state in which the human body is in an unhealthy state or an early cold state comprises;

when the abnormal condition of the human health is that the human body is in a temperature loss state, generating a plurality of different first heating signals based on the acquired human body arterial pressure corresponding to a plurality of different positions in the coverage area of the wearable equipment so as to control an infrared lamp in the wearable equipment to continuously emit light for a first time;

when the abnormal condition of the human health is that the human body is in an initial cold state, generating a plurality of different second heating signals based on the acquired human arterial pressure corresponding to a plurality of different positions in the coverage area of the wearable device so as to control the infrared lamp in the wearable device to continuously emit light for a second time length, wherein the second time length is longer than the first time length.

5. A wearable device, comprising:

the flexible substrate is in a closed ring shape;

the flexible substrate is provided with an acquisition unit, a control chip and a power supply;

the acquisition unit is used for acquiring the body surface temperature of the human body, the arterial pressure of the human body and/or the sound emitted by the human body in real time;

the control chip is used for acquiring human body health reference information with a duration set time according to real-time acquisition of human body surface temperature, human body arterial pressure and/or sound emitted by a human body, and determining abnormal human body health conditions according to the human body health reference information, wherein the abnormal human body health conditions comprise a temperature loss state or an initial cold state; and generating a mode control signal to the wearable device according to the abnormal condition of the human health so as to enable the wearable device to work in a corresponding mode, wherein the mode control signal comprises:

when the abnormal condition of the health of the human body is that the human body is in a temperature loss state or a cold initial state, generating a heating mode signal to control an infrared lamp on the wearable device to continuously emit light for a set time; when the abnormal condition of the human health is that a human body is in a temperature loss state or a cold initial state, generating a plurality of different heating signals based on the acquired human arterial pressure corresponding to a plurality of different positions in the coverage area of the wearable equipment, wherein each heating signal is used for respectively controlling the luminous intensity of each infrared lamp on the wearable equipment, and the luminous intensity of each infrared lamp is inversely proportional to the pressure corresponding to the position of the infrared lamp;

the power supply is used for providing working electric energy for the detection unit and the control chip.

6. The apparatus of claim 5, wherein the detection unit comprises a sound sensor, a plurality of temperature sensors, and a plurality of vibration sensors; the device also comprises an alarm element and a plurality of infrared lamps;

the sound sensor is used for collecting sound emitted by a human body in real time, the temperature sensor is used for collecting the temperature of the body surface of the human body in real time, and the vibration sensor is used for collecting the arterial pressure of the human body in real time;

the control chip, the power supply, the sound sensor and the alarm element are all arranged on the outer side of the flexible substrate;

the temperature sensors, the vibration sensors and the infrared lamps are alternately distributed on the inner side of the flexible substrate in an array manner;

the sound sensor, the alarm element, the temperature sensors, the vibration sensors and the infrared lamps are respectively connected with a control chip.

7. The apparatus of claim 6, further comprising:

and the packaging layer covers the plurality of temperature sensors, the plurality of vibration sensors and the plurality of infrared lamps so as to package the plurality of temperature sensors, the plurality of vibration sensors and the plurality of infrared lamps on the flexible substrate.

8. A computer-readable storage medium on which a computer program is stored, the program, when executed by a processor, implementing a method comprising:

acquiring human health reference information with duration, wherein the human health reference information at least comprises at least one of human body surface temperature information, pulse information and sounding information;

determining abnormal human health conditions according to the human health reference information; the abnormal condition of human health comprises a temperature loss state or an initial cold state;

generating a mode control signal for the wearable device according to the abnormal condition of the human health, so that the wearable device works in a corresponding mode;

the generating of the mode control signal to the wearable device according to the abnormal condition of the human health to enable the wearable device to work in a corresponding mode includes:

when the abnormal condition of the health of the human body is that the human body is in a temperature loss state or a cold initial state, generating a heating mode signal to control an infrared lamp on the wearable device to continuously emit light for a set time; when the abnormal condition of the human health is that a human body is in a temperature losing state or a cold initial state, a plurality of different heating signals are generated based on the acquired human arterial pressure corresponding to a plurality of different positions in the coverage area of the wearable device, each heating signal is used for respectively controlling the luminous intensity of each infrared lamp on the wearable device, and the luminous intensity of each infrared lamp is in inverse proportion to the pressure corresponding to the position of the infrared lamp.

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