CN114903457B - Dynamic blood pressure monitoring device and system for positive and negative correlation of human physiological parameters - Google Patents

Abstract

The invention belongs to the field of intelligent monitoring of dynamic blood pressure, and discloses a device and a system for monitoring the dynamic blood pressure of positive and negative association of physiological parameters of a human body. The method comprises the steps of acquiring a current blood pressure measured value of a user to be monitored in real time, and judging whether the current blood pressure measured value is in a normal blood pressure range or not; when the current blood pressure measured value is not in the normal blood pressure range, acquiring a historical blood pressure measured value of a user to be monitored; determining the blood pressure change rate of the user to be monitored according to the historical blood pressure measurement value and the current blood pressure measurement value; and determining a blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measurement value. Compared with the existing method that the user only can measure static blood pressure and the measured blood pressure is only punctiform data of a certain time point, the user can measure the blood pressure only when the health problem occurs, and further, a mode of treatment measures is adopted.

Description

Dynamic blood pressure monitoring device and system for positive and negative correlation of human physiological parameters

Technical Field

The invention relates to the technical field of intelligent monitoring of dynamic blood pressure, in particular to a device and a system for monitoring the dynamic blood pressure of positive and negative association of physiological parameters of a human body.

Background

The abnormal blood pressure is at great risk, and serious diseases possibly lead to death of patients; in addition, if the blood pressure is raised for a long time and the control is unstable, the target organs are damaged mostly along with the extension of time, wherein heart damage, cerebral vascular damage and kidney and fundus damage are more common. In addition, prolonged hypertension may cause symptoms such as inattention, hypomnesis, and numbness of the limbs in the patient. Hypertension is said to be more and more ill at present, and the ill people are younger and younger, but the whole Chinese awareness rate, the treatment rate and the standard rate are very low.

The foregoing is provided merely for the purpose of facilitating understanding of the technical solutions of the present invention and is not intended to represent an admission that the foregoing is prior art.

Disclosure of Invention

The invention mainly aims to provide a dynamic blood pressure monitoring device and a system for positive and negative association of human physiological parameters, and aims to solve the technical problems that in the prior art, blood pressure measurement is only carried out after health problems occur in users, early warning cannot be carried out on the blood pressure problems of the users in advance, and the trend of blood pressure changes of the users cannot be continuously and dynamically monitored.

In order to achieve the above object, the present invention provides a dynamic blood pressure monitoring device for positive and negative association of physiological parameters of a human body, the dynamic blood pressure monitoring device for positive and negative association of physiological parameters of a human body comprising: the device comprises a memory, a processor and a dynamic blood pressure monitoring program which is stored in the memory and can run on the processor and is related to the physiological parameters of the human body in positive and negative directions, wherein the dynamic blood pressure monitoring program which is related to the physiological parameters of the human body in positive and negative directions is configured to realize the following steps:

acquiring a current blood pressure measured value of a user to be monitored in real time, and judging whether the current blood pressure measured value is in a normal blood pressure range or not;

when the current blood pressure measured value is not in the normal blood pressure range, acquiring a historical blood pressure measured value of the user to be monitored;

determining the blood pressure change rate of the user to be monitored according to the historical blood pressure measured value and the current blood pressure measured value;

and determining a blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measured value.

Optionally, the dynamic blood pressure monitoring program of positive and negative association of the physiological parameters of the human body is configured to implement the following steps:

determining the blood pressure change trend of the user to be monitored according to the blood pressure change rate;

Determining a target blood pressure change trend according to the historical blood pressure measured value of the user to be monitored;

comparing the blood pressure change trend with the target blood pressure change trend to obtain a comparison result;

and determining the blood pressure monitoring result of the user to be monitored according to the comparison result and the current blood pressure measured value.

Optionally, the dynamic blood pressure monitoring program of positive and negative association of the physiological parameters of the human body is configured to implement the following steps:

acquiring physiological health information and historical activity tracks of a user to be monitored;

determining an ideal blood pressure range of the user to be monitored according to the physiological health information;

determining the activity rule of the user to be monitored in a preset period according to the historical activity track;

determining the blood pressure change information of the user to be monitored according to the activity rule;

and carrying out gain correction on the ideal blood pressure range according to the blood pressure change information to obtain the normal blood pressure range of the user to be monitored.

Optionally, the dynamic blood pressure monitoring program of positive and negative association of the physiological parameters of the human body is configured to implement the following steps:

selecting physiological parameters affecting the blood pressure of the user to be monitored from the physiological health information;

Inputting the physiological parameters into a preset ideal blood pressure prediction model for prediction to obtain a prediction result;

and determining the ideal blood pressure range of the user to be monitored according to the prediction result.

Optionally, the dynamic blood pressure monitoring program of positive and negative association of the physiological parameters of the human body is configured to implement the following steps:

determining the activity type of each moment corresponding to the activity rule;

determining a blood pressure fluctuation trend corresponding to the activity type according to a preset blood pressure fluctuation factor table;

determining fluctuation information of blood pressure according to the blood pressure fluctuation trend;

and determining the blood pressure change information of the user to be monitored according to the fluctuation information and the activity time corresponding to the activity type.

Optionally, the dynamic blood pressure monitoring program of positive and negative association of the physiological parameters of the human body is configured to implement the following steps:

acquiring a current blood pressure measured value of a user to be monitored in real time;

determining the measurement time corresponding to the current blood pressure measurement value;

searching a target blood pressure range from the normal blood pressure range according to the measurement time;

and judging whether the current blood pressure measured value is in the target blood pressure range or not.

Optionally, the dynamic blood pressure monitoring program of positive and negative association of the physiological parameters of the human body is configured to implement the following steps:

When the current blood pressure measured value is not in the normal blood pressure range, judging whether the current blood pressure measured value is larger than the upper limit value of the normal blood pressure range or not;

when the current blood pressure measured value is larger than the upper limit value of the normal blood pressure range, acquiring the historical heart rate of the user to be monitored;

judging the heart rate variation trend of the user to be monitored according to the historical heart rate;

and when the heart rate change trend is an ascending trend, sending out alarm information and notifying the contact person of the user to be monitored.

Optionally, the dynamic blood pressure monitoring program of positive and negative association of the physiological parameters of the human body is configured to implement the following steps:

judging whether the blood pressure of the user to be monitored is abnormal or not according to the blood pressure monitoring result;

and when the blood pressure of the user to be monitored is abnormal, sending alarm information and informing the contact person of the user to be monitored.

In addition, in order to achieve the above object, the present invention also provides a dynamic blood pressure monitoring system for positive and negative association of physiological parameters of a human body, the system comprising: the device comprises a measurement module, an acquisition module, a blood pressure change rate determination module and a blood pressure monitoring result determination module;

the measuring module is used for acquiring the current blood pressure measured value of the user to be monitored in real time and judging whether the current blood pressure measured value is in a normal blood pressure range or not;

The acquisition module is used for acquiring the historical blood pressure measured value of the user to be monitored when the current blood pressure measured value is not in the normal blood pressure range;

the blood pressure change rate determining module is used for determining the blood pressure change rate of the user to be monitored according to the historical blood pressure measured value and the current blood pressure measured value;

the blood pressure monitoring result determining module is used for determining the blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measured value.

In addition, in order to achieve the above object, the present invention further provides a storage medium, on which a dynamic blood pressure monitoring program related to the positive and negative physiological parameters of a human body is stored, wherein the dynamic blood pressure monitoring program related to the positive and negative physiological parameters of the human body, when executed by a processor, implements the following steps:

acquiring a current blood pressure measured value of a user to be monitored in real time, and judging whether the current blood pressure measured value is in a normal blood pressure range or not;

when the current blood pressure measured value is not in the normal blood pressure range, acquiring a historical blood pressure measured value of the user to be monitored;

determining the blood pressure change rate of the user to be monitored according to the historical blood pressure measured value and the current blood pressure measured value;

And determining a blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measured value.

The method comprises the steps of acquiring a current blood pressure measured value of a user to be monitored in real time, and judging whether the current blood pressure measured value is in a normal blood pressure range or not; when the current blood pressure measured value is not in the normal blood pressure range, acquiring a historical blood pressure measured value of a user to be monitored; determining the blood pressure change rate of the user to be monitored according to the historical blood pressure measurement value and the current blood pressure measurement value; and determining a blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measurement value. Compared with the existing method that the user only can measure static blood pressure and the measured blood pressure is only punctiform data of a certain time point, the user can measure the blood pressure only when the health problem occurs, and further, a mode of treatment measures is adopted.

Drawings

FIG. 1 is a schematic diagram of a dynamic blood pressure monitoring device with positive and negative correlation of human physiological parameters in a hardware operating environment according to an embodiment of the present invention;

FIG. 2 is a schematic flow chart of a first embodiment of a dynamic blood pressure monitor device for positive and negative correlation of physiological parameters of a human body according to the present invention;

FIG. 3 is a flow chart of a second embodiment of the dynamic blood pressure monitor device of the present invention for positive and negative correlation of physiological parameters of human body;

fig. 4 is a block diagram of a dynamic blood pressure monitoring system with positive and negative correlation of physiological parameters of a human body according to a first embodiment of the present invention.

The achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a dynamic blood pressure monitoring device with positive and negative correlation of human physiological parameters in a hardware operation environment according to an embodiment of the present invention.

As shown in fig. 1, the dynamic blood pressure monitoring device with positive and negative correlation of human physiological parameters may include: a processor 1001, such as a central processing unit (Central Processing Unit, CPU), a communication bus 1002, a user interface 1003, a network interface 1004, a memory 1005. Wherein the communication bus 1002 is used to enable connected communication between these components. The user interface 1003 may include a Display, an input unit such as a Keyboard (Keyboard), and the optional user interface 1003 may further include a standard wired interface, a wireless interface. The network interface 1004 may optionally include a standard wired interface, a Wireless interface (e.g., a Wireless-Fidelity (WI-FI) interface). The Memory 1005 may be a high-speed random access Memory (Random Access Memory, RAM) Memory or a stable nonvolatile Memory (NVM), such as a disk Memory. The memory 1005 may also optionally be a storage device separate from the processor 1001 described above.

It will be appreciated by those skilled in the art that the structure shown in fig. 1 does not constitute a limitation of the dynamic blood pressure monitoring device in positive and negative association of physiological parameters of the human body, and may include more or fewer components than shown, or may combine certain components, or a different arrangement of components.

As shown in fig. 1, a memory 1005 as a storage medium may include an operating system, a data storage module, a network communication module, a user interface module, and a dynamic blood pressure monitoring program for positive and negative association of physiological parameters of a human body.

In the dynamic blood pressure monitoring device with positive and negative correlation of human physiological parameters shown in fig. 1, the network interface 1004 is mainly used for data communication with a network server; the user interface 1003 is mainly used for data interaction with a user; the dynamic blood pressure monitoring device with positive and negative correlation of the physiological parameters of the human body invokes the dynamic blood pressure monitoring program with positive and negative correlation of the physiological parameters of the human body stored in the memory 1005 through the processor 1001.

Referring to fig. 2, fig. 2 is a flow chart of a first embodiment of a dynamic blood pressure monitoring device with positive and negative correlation of physiological parameters of a human body according to the present invention.

The embodiment of the invention provides a dynamic blood pressure monitoring device for positive and negative association of human physiological parameters, which comprises: the device comprises a memory, a processor and a dynamic blood pressure monitoring program which is stored in the memory and can run on the processor and is related to the physiological parameters of the human body in positive and negative directions, wherein the dynamic blood pressure monitoring program which is related to the physiological parameters of the human body in positive and negative directions is configured to realize the following steps: in this embodiment, the dynamic blood pressure monitoring device for positive and negative association of physiological parameters of a human body includes the following steps:

Step S10: and acquiring the current blood pressure measured value of the user to be monitored in real time, and judging whether the current blood pressure measured value is in a normal blood pressure range or not.

It should be noted that, the dynamic blood pressure monitoring device with positive and negative correlation of the physiological parameters of the human body in the embodiment may be a device which is convenient for the user to wear and can measure the physical health signs such as the blood pressure and the heart rate of the user in real time. Such as smart bracelets, smart vests, etc. The real-time acquisition of the current blood pressure measured value of the user to be monitored may be that the blood pressure of the user to be monitored is acquired in real time through the dynamic blood pressure monitoring device with positive and negative correlation of the physiological parameters of the human body. The normal blood pressure range can enable the blood pressure range which is determined in advance according to the physical health information and the activity information of the user to be monitored and is special for the user to be monitored, and when the current blood pressure measured value of the user to be monitored is in the normal blood pressure range, the blood pressure of the user to be monitored is judged to be normal.

Further, in order to more accurately determine whether the user has an early blood pressure risk, the step S10 may include: acquiring a current blood pressure measured value of a user to be monitored in real time; determining the measurement time corresponding to the current blood pressure measurement value; searching a target blood pressure range from the normal blood pressure range according to the measurement time; and judging whether the current blood pressure measured value is in the target blood pressure range or not.

It should be noted that, the target blood pressure range may be a normal blood pressure range of the user corresponding to the measurement time, and at different moments, because the current activities of the user are different, the blood pressure of the user may change due to the current activities of the user, so the normal blood pressure range of the user is not a fixed range, but the normal blood pressure ranges of the user are different at different moments. Therefore, it is necessary to acquire a measurement time corresponding to the current blood pressure measurement value, and determine a normal blood pressure range of the user at the measurement time, that is, the target blood pressure range, according to the measurement time.

Further, in order to more accurately determine whether the user has an early blood pressure risk, after the step S10, the method may include: when the current blood pressure measured value is not in the normal blood pressure range, judging whether the current blood pressure measured value is larger than the upper limit value of the normal blood pressure range or not; when the current blood pressure measured value is larger than the upper limit value of the normal blood pressure range, acquiring the historical heart rate of the user to be monitored; judging the heart rate variation trend of the user to be monitored according to the historical heart rate; and when the heart rate change trend is an ascending trend, sending out alarm information and notifying the contact person of the user to be monitored.

It should be noted that the normal blood pressure range may be a blood pressure range corresponding to a measurement time corresponding to the current blood pressure measurement value. The historical heart rate can be the heart rate of the user to be monitored in the current period of time, the heart rate of the user to be monitored in the current period of time can be the heart rate of the last hour or half hour, and the heart rate change trend can be the overall change trend of the historical heart rate in the current period of time, and can be the rising trend, the falling trend or the stable fluctuation. When the heart rate change trend is an ascending trend, it can be determined that the blood pressure of the user to be monitored may continue to rise, so that alarm information is sent out and contacts of the user to be monitored are notified.

Step S20: and when the current blood pressure measured value is not in the normal blood pressure range, acquiring the historical blood pressure measured value of the user to be monitored.

It should be noted that the historical blood pressure measurement value may be a blood pressure measurement value of the user to be monitored in a previous period of time, and may include a blood pressure measurement value within a week or a month.

Step S30: and determining the blood pressure change rate of the user to be monitored according to the historical blood pressure measured value and the current blood pressure measured value.

It should be noted that the blood pressure change rate may be a blood pressure change rate of the user to be monitored, which is determined according to the current blood pressure measurement value and the historical blood pressure measurement value, and may be a blood pressure change rate in a continuous period of time, for example, a blood pressure change rate between one hour or one hour. For example, the blood pressure value of the user to be monitored at 11 points 59 minutes: the blood pressure change rate is obtained by subtracting a historical blood pressure measured value from a current blood pressure measured value, the systolic blood pressure change rate is 94-92=2, the diastolic blood pressure change rate is 88-80=8, and a plurality of change values exist in a period of time.

Step S40: and determining a blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measured value.

It should be noted that, since the blood pressure change rate is the current blood pressure measurement value minus the historical blood pressure measurement value, if the blood pressure change rate is greater than 0, it is indicated that the blood pressure of the user to be monitored is an upward trend, and if the blood pressure change rate is less than 0, it is indicated that the blood pressure of the user to be monitored is a downward trend. The determining the blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measurement value may be determining the blood pressure monitoring result of the user to be monitored according to the current blood pressure measurement value and the trend of rising or falling of the blood pressure. For example, the current blood pressure measurement value of the user to be monitored is not in the normal blood pressure range and is also higher than the upper limit value of the normal blood pressure range, the current blood pressure change rate is positive, but among the blood pressure change rates, a plurality of blood pressure change rates adjacent to the current blood pressure change rate are taken, and the number ratio of rising and falling trends in the blood pressure change rates is 0.9:1, less than a preset blood pressure change threshold 1:1. and the blood pressure of the user to be monitored fluctuates in a relatively balanced manner and has a descending trend, and the condition that the blood pressure of the user to be monitored is not abnormal is judged. If the number ratio of the rising and falling trends in the blood pressure change rate is 1.5:1, it can be known that the current blood pressure fluctuation trend is generally an ascending trend, and the current blood pressure measurement value is greater than the upper limit value of the normal blood pressure range, at this time, the blood pressure monitoring result is that the blood pressure of the user to be monitored is abnormal, and alarm information is sent out and the contact person of the user to be monitored is notified. And when the blood pressure of the user to be monitored is abnormal, sending alarm information and informing the contact person of the user to be monitored. The contact person can be a preset guardian of the user to be monitored when the blood pressure is abnormal. May be one or more.

Further, in order to obtain a more accurate blood pressure monitoring result and achieve the purpose of early warning the risk of blood pressure, the step S40 may include: determining the blood pressure change trend of the user to be monitored according to the blood pressure change rate; determining a target blood pressure change trend according to the historical blood pressure measured value of the user to be monitored; comparing the blood pressure change trend with the target blood pressure change trend to obtain a comparison result; and determining the blood pressure monitoring result of the user to be monitored according to the comparison result and the current blood pressure measured value.

The determining the blood pressure change trend of the user to be monitored according to the blood pressure change rate may be determining that the blood pressure change trend is an increasing trend when the blood pressure change rate is positive, and determining that the blood pressure change trend is a decreasing trend when the blood pressure change rate is negative. The target blood pressure trend may be a blood pressure trend within a period corresponding to the historical blood pressure measurement. The determining the target blood pressure change trend according to the historical blood pressure measurement value of the user to be monitored may be determining whether the blood pressure of the user to be monitored is in a continuous rising or continuous falling trend according to the historical blood pressure measurement value. If the blood pressure of the user to be monitored is not in the continuous rising or continuous falling trend, calculating a blood pressure change value corresponding to the historical blood pressure measurement value, for example, the historical blood pressure measurement value is a blood pressure measurement value in the last hour, calculating a historical blood pressure change rate according to the historical blood pressure measurement value, selecting a preset number of blood pressure measurement values from the historical blood pressure measurement value, selecting blood pressures at equal intervals, determining the blood pressure change rate among the selected blood pressure measurement values, and determining the ratio of the times that the blood pressure change rate is greater than zero to the times that the blood pressure change rate is less than zero according to the mode of calculating the blood pressure change rate, wherein when the frequency ratio is less than 1:1, the target blood pressure change trend is determined to be the falling trend, when the frequency ratio is greater than 1:1, the target blood pressure change trend is determined to be the rising trend, and when the frequency ratio is equal to 1:1, the target blood pressure change trend is determined to be uniform fluctuation. And comparing the blood pressure change trend with the target blood pressure change trend, wherein the comparison result can be obtained by judging whether the blood pressure change trend is consistent with the target blood pressure change trend. If the blood pressure trend is consistent, the blood pressure trend is inconsistent. And determining the blood pressure monitoring result of the user to be monitored according to the comparison result and the current blood pressure measured value, wherein if the blood pressure trend in the comparison result is consistent and the current blood pressure measured value is not in the normal blood pressure range, the blood pressure monitoring result of the user to be monitored is judged to be abnormal. If the blood pressure trend in the comparison result is inconsistent and the current blood pressure measured value of the user to be monitored returns to the normal blood pressure range, judging that the blood pressure monitoring result of the user to be monitored is normal.

The method comprises the steps of obtaining a current blood pressure measured value of a user to be monitored in real time, and judging whether the current blood pressure measured value is in a normal blood pressure range or not; when the current blood pressure measured value is not in the normal blood pressure range, acquiring a historical blood pressure measured value of a user to be monitored; determining the blood pressure change rate of the user to be monitored according to the historical blood pressure measurement value and the current blood pressure measurement value; and determining a blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measurement value. Compared with the existing method that a user can only measure static blood pressure and the measured blood pressure is only punctiform data of a certain time point, the user can only measure the blood pressure when a health problem occurs, and further, a mode of treatment measures is adopted, the dynamic blood pressure of the user can be measured in real time, and the early blood pressure abnormal risk of the user can be found in time according to the historical blood pressure measured value.

Referring to fig. 3, fig. 3 is a flow chart of a second embodiment of the dynamic blood pressure monitoring device with positive and negative correlation of physiological parameters of a human body according to the present invention.

Based on the first embodiment, in this embodiment, before step S10, the method further includes:

step S01: and acquiring physiological health information and historical activity tracks of the user to be monitored.

It should be noted that the physiological health information may be physical health information of the user to be monitored, for example, whether the user is obese, has a disease such as hypertension, myocardial infarction, angina pectoris, and the like, and information such as weight. The historical activity track may be a daily activity path and a work habit of the user to be monitored, and the work habit may include things that the user to be monitored does at various time points, such as running, bathing, body building, sleeping, and the like.

Step S02: and determining an ideal blood pressure range of the user to be monitored according to the physiological health information.

It should be noted that, the information of age, weight, disease, etc. of each person may have a certain influence on blood pressure, for example, if only meeting the condition that the blood pressure is less than 140/90, it is definitely not feasible, and even < 130/80 is not ideal blood pressure; for those with a body mass index of less than 24, a blood pressure of 130/80 is desirable, whereas for those with a body mass index of greater than or equal to 24, a blood pressure of less than 120/80 is desirable. So that the risk of cardiovascular and cerebrovascular diseases can be effectively reduced. As another example, normal hypertension may be aimed at a first level of less than 140/90 and at a second level of 130/80, or even 120/80. However, for patients with combined diabetes, the first goal is 130/80; for patients with heart failure, myocardial infarction, angina, aortic dissection and the like, the aim of controlling blood pressure is not 140/90, but is as low as 130/80 as possible, and even 120/70 is more ideal in some cases.

Further, in order to obtain the ideal blood pressure range of the user to be monitored and achieve the purpose of early warning the blood pressure risk, the step S02 may include: selecting physiological parameters affecting the blood pressure of the user to be monitored from the physiological health information; inputting the physiological parameters into a preset ideal blood pressure prediction model for prediction to obtain a prediction result; and determining the ideal blood pressure range of the user to be monitored according to the prediction result.

It should be noted that the physiological parameter may be a factor that can affect the blood pressure of the user to be monitored, such as weight, disease, and age. The preset ideal blood pressure prediction model may be a pre-trained model capable of predicting an ideal blood pressure range of the user based on physiological parameters of the user.

Step S03: and determining the activity rule of the user to be monitored in a preset period according to the historical activity track.

It should be noted that the preset period may be a preset period, typically a day, and in a special case, may be a week. The activity law may be activity events and time of the user to be monitored in the period, for example, the activity law of the user to be monitored may be 7 o 'clock getting up in the morning, 8 o' clock morning exercise, 9 o 'clock rest, running at 6 o' clock afternoon, etc.

Step S04: and determining the blood pressure change information of the user to be monitored according to the activity rule.

It should be noted that, the determining the blood pressure change information of the user to be monitored according to the activity rule may be determining, according to the activity rule, a blood pressure change possibly caused by an activity in the activity rule, for example, if the current activity is running, the current blood pressure change information may be that the blood pressure has an ascending trend.

Further, in order to obtain a more accurate normal blood pressure range of the user to be monitored, the step S04 may include: determining the activity type of each moment corresponding to the activity rule; determining a blood pressure fluctuation trend corresponding to the activity type according to a preset blood pressure fluctuation factor table; determining fluctuation information of blood pressure according to the blood pressure fluctuation trend; and determining the blood pressure change information of the user to be monitored according to the fluctuation information and the activity time corresponding to the activity type.

It should be noted that the activity types may include physical activities, mental activities, satiety, sleep, and the like. The preset blood pressure fluctuation factor table may include an activity type and a corresponding blood pressure fluctuation trend thereof, for example, in sports, blood pressure is an ascending trend; during sleep, blood pressure decreases; the user may be mental stress during mental activities, and the blood pressure may be in an ascending trend. The determining the blood pressure fluctuation information according to the blood pressure fluctuation trend may be determining whether the blood pressure will have fluctuation such as rising or falling according to the blood pressure fluctuation trend corresponding to each activity type in a preset blood pressure fluctuation factor table. The blood pressure change information may be rising or falling fluctuation information of the blood pressure of the user to be monitored over time in the preset period, that is, blood pressure trend information of each moment.

Step S05: and carrying out gain correction on the ideal blood pressure range according to the blood pressure change information to obtain the normal blood pressure range of the user to be monitored.

It should be noted that, the normal blood pressure range may be a smaller blood pressure range of the user determined according to the blood pressure change information of the user and the ideal blood pressure range, when the blood pressure of the user is within the normal blood pressure range, it may be determined that the user has no blood pressure risk, and when the blood pressure of the user is not within the normal blood pressure range, it may not be determined that the blood pressure of the user is abnormal directly, and further determination is required according to the blood pressure change condition of the user. The gain correction of the ideal blood pressure range according to the blood pressure variation information may be to increase the upper limit value of the ideal blood pressure range at the activity time of the activity type corresponding to the blood pressure variation information if the blood pressure trend in the blood pressure variation information is an increasing trend, and the specific increasing value may be a value corresponding to the activity type in the preset blood pressure fluctuation factor table, for example, the current blood pressure variation information is an increasing value, the corresponding activity type is a sports motion, and the blood pressure fluctuation value corresponding to the sports motion in the preset blood pressure fluctuation factor table is 3, and the normal blood pressure range at the time corresponding to the blood pressure variation information is a blood pressure range obtained by increasing the upper limit value and the lower limit value of the ideal blood pressure range by 3. The specific value for correcting the ideal blood pressure according to the blood pressure change information may be a preset fixed value, for example, when the blood pressure change information is an upward trend, the upper limit value and the lower limit value of the ideal blood pressure range are each added by 5 to determine the normal blood pressure range. The present embodiment is not limited herein.

In a specific implementation, when a user gets up at 6 o 'clock and exercises at 8 o' clock, the activity type of the user at 8 o 'clock is sports, the corresponding blood pressure fluctuation trend is determined to be an ascending trend according to a preset blood pressure fluctuation factor table, the ideal blood pressure range of the user is 130/80, and the fluctuation value corresponding to sports is 5 according to the preset blood pressure fluctuation factor table, so that the normal blood pressure range of the user at 8 o' clock can be 135/85.

The method comprises the steps of obtaining physiological health information and historical activity tracks of a user to be monitored; determining an ideal blood pressure range of the user to be monitored according to the physiological health information; determining an activity rule of the user to be monitored in a preset period according to the historical activity track, and determining blood pressure change information of the user to be monitored according to the activity rule; and carrying out gain correction on the ideal blood pressure range according to the blood pressure change information to obtain the normal blood pressure range of the user to be monitored. According to the method and the device, the normal blood pressure range of the user to be monitored is determined through the physiological health information and the historical activity track of the user to be monitored, so that early blood pressure risk of the user to be monitored can be judged more accurately.

Referring to fig. 4, fig. 4 is a block diagram of a first embodiment of a dynamic blood pressure monitoring system for positive and negative correlation of physiological parameters of a human body according to the present invention.

As shown in fig. 4, the dynamic blood pressure monitoring system for positive and negative correlation of physiological parameters of a human body according to the embodiment of the present invention includes: the blood pressure monitoring device comprises a measurement module 10, an acquisition module 20, a blood pressure change rate determination module 30 and a blood pressure monitoring result determination module 40;

the measurement module 10 is configured to obtain a current blood pressure measurement value of a user to be monitored in real time, and determine whether the current blood pressure measurement value is within a normal blood pressure range;

the acquiring module 20 is configured to acquire a historical blood pressure measurement value of the user to be monitored when the current blood pressure measurement value is not within the normal blood pressure range;

the blood pressure change rate determining module 30 is configured to determine a blood pressure change rate of the user to be monitored according to the historical blood pressure measurement value and the current blood pressure measurement value;

the blood pressure monitoring result determining module 40 is configured to determine a blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measurement value.

The method comprises the steps of obtaining a current blood pressure measured value of a user to be monitored in real time, and judging whether the current blood pressure measured value is in a normal blood pressure range or not; when the current blood pressure measured value is not in the normal blood pressure range, acquiring a historical blood pressure measured value of a user to be monitored; determining the blood pressure change rate of the user to be monitored according to the historical blood pressure measurement value and the current blood pressure measurement value; and determining a blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measurement value. Compared with the existing method that a user can only measure static blood pressure and the measured blood pressure is only punctiform data of a certain time point, the user can only measure the blood pressure when a health problem occurs, and further, a mode of treatment measures is adopted, the dynamic blood pressure of the user can be measured in real time, and the early blood pressure abnormal risk of the user can be found in time according to the historical blood pressure measured value.

It should be noted that the above-described working procedure is merely illustrative, and does not limit the scope of the present invention, and in practical application, a person skilled in the art may select part or all of them according to actual needs to achieve the purpose of the embodiment, which is not limited herein.

In addition, technical details that are not described in detail in this embodiment may refer to the parameter operation method provided in any embodiment of the present invention, and are not described herein again.

Based on the first embodiment of the dynamic blood pressure monitoring system with positive and negative correlation of the human physiological parameters, a second embodiment of the dynamic blood pressure monitoring system with positive and negative correlation of the human physiological parameters is provided.

In this embodiment, the blood pressure monitoring result determining module 40 is further configured to determine a blood pressure change trend of the user to be monitored according to the blood pressure change rate; determining a target blood pressure change trend according to the historical blood pressure measured value of the user to be monitored; comparing the blood pressure change trend with the target blood pressure change trend to obtain a comparison result; and determining the blood pressure monitoring result of the user to be monitored according to the comparison result and the current blood pressure measured value.

Further, the measurement module 10 is further configured to obtain physiological health information and a historical activity track of the user to be monitored; determining an ideal blood pressure range of the user to be monitored according to the physiological health information; determining the activity rule of the user to be monitored in a preset period according to the historical activity track; determining the blood pressure change information of the user to be monitored according to the activity rule; and carrying out gain correction on the ideal blood pressure range according to the blood pressure change information to obtain the normal blood pressure range of the user to be monitored.

Further, the measurement module 10 is further configured to select a physiological parameter affecting the blood pressure of the user to be monitored from the physiological health information; inputting the physiological parameters into a preset ideal blood pressure prediction model for prediction to obtain a prediction result; and determining the ideal blood pressure range of the user to be monitored according to the prediction result.

Further, the measurement module 10 is further configured to determine an activity type at each moment corresponding to the activity rule; determining a blood pressure fluctuation trend corresponding to the activity type according to a preset blood pressure fluctuation factor table; determining fluctuation information of blood pressure according to the blood pressure fluctuation trend; and determining the blood pressure change information of the user to be monitored according to the fluctuation information and the activity time corresponding to the activity type.

Further, the measurement module 10 is further configured to obtain, in real time, a current blood pressure measurement value of the user to be monitored; determining the measurement time corresponding to the current blood pressure measurement value; searching a target blood pressure range from the normal blood pressure range according to the measurement time; and judging whether the current blood pressure measured value is in the target blood pressure range or not.

Further, the measurement module 10 is further configured to determine, when the current blood pressure measurement value is not within the normal blood pressure range, whether the current blood pressure measurement value is greater than an upper limit value of the normal blood pressure range; when the current blood pressure measured value is larger than the upper limit value of the normal blood pressure range, acquiring the historical heart rate of the user to be monitored; judging the heart rate variation trend of the user to be monitored according to the historical heart rate; and when the heart rate change trend is an ascending trend, sending out alarm information and notifying the contact person of the user to be monitored.

Further, the blood pressure monitoring result determining module 40 is further configured to determine whether the blood pressure of the user to be monitored is abnormal according to the blood pressure monitoring result; and when the blood pressure of the user to be monitored is abnormal, sending alarm information and informing the contact person of the user to be monitored.

Other embodiments or specific implementation manners of the dynamic blood pressure monitoring system with positive and negative correlation of human physiological parameters can refer to the above method embodiments, and are not described herein.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or system. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or system that comprises the element.

The foregoing embodiment numbers of the present invention are merely for the purpose of description, and do not represent the advantages or disadvantages of the embodiments.

From the above description of the embodiments, it will be clear to those skilled in the art that the above-described embodiment method may be implemented by means of software plus a necessary general hardware platform, but of course may also be implemented by means of hardware, but in many cases the former is a preferred embodiment. Based on such understanding, the technical solution of the present invention may be embodied essentially or in a part contributing to the prior art in the form of a software product stored in a storage medium (e.g. read-only memory/random-access memory, magnetic disk, optical disk), comprising instructions for causing a terminal device (which may be a mobile phone, a computer, a server, or a network device, etc.) to perform the method according to the embodiments of the present invention.

The foregoing description is only of the preferred embodiments of the present invention, and is not intended to limit the scope of the invention, but rather is intended to cover any equivalents of the structures or equivalent processes disclosed herein or in the alternative, which may be employed directly or indirectly in other related arts.

Claims (6)

1. The utility model provides a human physiological parameter positive negative correlation's dynamic blood pressure monitoring device which characterized in that, human physiological parameter positive negative correlation's dynamic blood pressure monitoring device includes: the device comprises a memory, a processor and a dynamic blood pressure monitoring program which is stored in the memory and can run on the processor and is related to the physiological parameters of the human body in positive and negative directions, wherein the dynamic blood pressure monitoring program which is related to the physiological parameters of the human body in positive and negative directions is configured to realize the following steps:

acquiring a current blood pressure measured value of a user to be monitored in real time, and judging whether the current blood pressure measured value is in a normal blood pressure range or not;

when the current blood pressure measured value is not in the normal blood pressure range, acquiring a historical blood pressure measured value of the user to be monitored;

determining the blood pressure change rate of the user to be monitored according to the historical blood pressure measured value and the current blood pressure measured value;

Determining a blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measurement value;

the dynamic blood pressure monitoring program configuration of the positive and negative association of the physiological parameters of the human body further comprises the following steps:

acquiring physiological health information and historical activity tracks of a user to be monitored;

determining an ideal blood pressure range of the user to be monitored according to the physiological health information;

determining the activity rule of the user to be monitored in a preset period according to the historical activity track;

determining the blood pressure change information of the user to be monitored according to the activity rule;

gain correction is carried out on the ideal blood pressure range according to the blood pressure change information, and a normal blood pressure range of the user to be monitored is obtained;

the step of determining the blood pressure change information of the user to be monitored according to the activity rule comprises the following steps:

determining the activity type of each moment corresponding to the activity rule;

determining a blood pressure fluctuation trend corresponding to the activity type according to a preset blood pressure fluctuation factor table;

determining fluctuation information of blood pressure according to the blood pressure fluctuation trend;

determining the blood pressure change information of the user to be monitored according to the fluctuation information and the activity time corresponding to the activity type;

The step of determining the blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measurement value comprises the following steps:

determining the blood pressure change trend of the user to be monitored according to the blood pressure change rate;

determining a target blood pressure change trend according to the historical blood pressure measured value of the user to be monitored;

comparing the blood pressure change trend with the target blood pressure change trend to obtain a comparison result;

determining a blood pressure monitoring result of the user to be monitored according to the comparison result and the current blood pressure measurement value;

the step of determining the blood pressure monitoring result of the user to be monitored according to the comparison result and the current blood pressure measured value comprises the following steps:

if the blood pressure trend in the comparison result is consistent and the current blood pressure measured value is not in the normal blood pressure range, judging that the blood pressure monitoring result of the user to be monitored is abnormal blood pressure;

if the blood pressure trend in the comparison result is inconsistent and the current blood pressure measured value of the user to be monitored returns to the normal blood pressure range, judging that the blood pressure monitoring result of the user to be monitored is normal.

2. The device for dynamic blood pressure monitoring of positive and negative associations of physiological parameters of a human body according to claim 1, wherein the program for dynamic blood pressure monitoring of positive and negative associations of physiological parameters of a human body is configured to implement the steps of:

Selecting physiological parameters affecting the blood pressure of the user to be monitored from the physiological health information;

inputting the physiological parameters into a preset ideal blood pressure prediction model for prediction to obtain a prediction result;

and determining the ideal blood pressure range of the user to be monitored according to the prediction result.

3. The device for dynamic blood pressure monitoring of positive and negative associations of physiological parameters of a human body according to claim 1, wherein the program for dynamic blood pressure monitoring of positive and negative associations of physiological parameters of a human body is configured to implement the steps of:

acquiring a current blood pressure measured value of a user to be monitored in real time;

determining the measurement time corresponding to the current blood pressure measurement value;

searching a target blood pressure range from the normal blood pressure range according to the measurement time;

and judging whether the current blood pressure measured value is in the target blood pressure range or not.

4. The device for dynamic blood pressure monitoring of positive and negative associations of physiological parameters of a human body according to claim 1, wherein the program for dynamic blood pressure monitoring of positive and negative associations of physiological parameters of a human body is configured to implement the steps of:

when the current blood pressure measured value is not in the normal blood pressure range, judging whether the current blood pressure measured value is larger than the upper limit value of the normal blood pressure range or not;

When the current blood pressure measured value is larger than the upper limit value of the normal blood pressure range, acquiring the historical heart rate of the user to be monitored;

judging the heart rate variation trend of the user to be monitored according to the historical heart rate;

and when the heart rate change trend is an ascending trend, sending out alarm information and notifying the contact person of the user to be monitored.

5. The device for dynamic blood pressure monitoring of positive and negative associations of physiological parameters of a human body according to claim 2, wherein the program for dynamic blood pressure monitoring of positive and negative associations of physiological parameters of a human body is configured to implement the steps of:

judging whether the blood pressure of the user to be monitored is abnormal or not according to the blood pressure monitoring result;

and when the blood pressure of the user to be monitored is abnormal, sending alarm information and informing the contact person of the user to be monitored.

6. The utility model provides a human physiological parameter positive negative correlation's dynamic blood pressure monitoring system which characterized in that, human physiological parameter positive negative correlation's dynamic blood pressure monitoring system includes: the device comprises a measurement module, an acquisition module, a blood pressure change rate determination module and a blood pressure monitoring result determination module;

the measuring module is used for acquiring the current blood pressure measured value of the user to be monitored in real time and judging whether the current blood pressure measured value is in a normal blood pressure range or not;

The acquisition module is used for acquiring the historical blood pressure measured value of the user to be monitored when the current blood pressure measured value is not in the normal blood pressure range;

the blood pressure change rate determining module is used for determining the blood pressure change rate of the user to be monitored according to the historical blood pressure measured value and the current blood pressure measured value;

the blood pressure monitoring result determining module is used for determining the blood pressure monitoring result of the user to be monitored according to the blood pressure change rate and the current blood pressure measured value;

the measuring module is also used for acquiring physiological health information and historical activity tracks of the user to be monitored; determining an ideal blood pressure range of the user to be monitored according to the physiological health information; determining the activity rule of the user to be monitored in a preset period according to the historical activity track; determining the blood pressure change information of the user to be monitored according to the activity rule; gain correction is carried out on the ideal blood pressure range according to the blood pressure change information, and a normal blood pressure range of the user to be monitored is obtained;

the measuring module is also used for determining the activity type of each moment corresponding to the activity rule; determining a blood pressure fluctuation trend corresponding to the activity type according to a preset blood pressure fluctuation factor table; determining fluctuation information of blood pressure according to the blood pressure fluctuation trend; determining the blood pressure change information of the user to be monitored according to the fluctuation information and the activity time corresponding to the activity type;

The blood pressure monitoring result determining module is used for determining the blood pressure change trend of the user to be monitored according to the blood pressure change rate; determining a target blood pressure change trend according to the historical blood pressure measured value of the user to be monitored; comparing the blood pressure change trend with the target blood pressure change trend to obtain a comparison result; determining a blood pressure monitoring result of the user to be monitored according to the comparison result and the current blood pressure measurement value;

the blood pressure monitoring result determining module is used for determining that the blood pressure monitoring result of the user to be monitored is abnormal if the blood pressure trend in the comparison result is consistent and the current blood pressure measured value is not in the normal blood pressure range; if the blood pressure trend in the comparison result is inconsistent and the current blood pressure measured value of the user to be monitored returns to the normal blood pressure range, judging that the blood pressure monitoring result of the user to be monitored is normal.

Images