CN111481191A - Adjusting system based on electrocardio sensor parameter - Google Patents

Abstract

The invention relates to the technical field of an electrocardio sensor, in particular to an adjusting system based on electrocardio sensor parameters, wherein the adjusting system comprises: the acquisition module is arranged in the electrocardio sensor and is used for acquiring cardiac data of a user wearing the electrocardio sensor; the detection module is arranged in the electrocardio sensor and connected with the acquisition module, and detects the real-time behavior state of a user wearing the electrocardio sensor according to the heart data; and the switching module is arranged on the electrocardio sensor and connected with the detection module, and switches the electrocardio sensor between the collection of the electrocardio data and the collection of the heart rate data according to the real-time behavior state. The technical scheme of the invention has the beneficial effects that: the real-time behavior state of the wearing user is detected through the detection module according to the heart data, the electrocardio sensor is switched between the collected electrocardio data and the collected heart rate data through the switching module according to the real-time behavior state, and the heart data of the user can be collected in a large scale in real time.

Description

Adjusting system based on electrocardio sensor parameter

Technical Field

The invention relates to the technical field of an electrocardio sensor, in particular to an adjusting system based on electrocardio sensor parameters.

Background

The current electrocardio sensor only reads one of the transmission electrocardio data and the heart rate data, and the electrocardio sensor does not identify the personal identity information and other physical sign parameter information of the wearer. When point-to-point data acquisition and transmission are carried out, the identity information and other physical sign parameters of a user can only be input on a receiving end and participate in analysis and judgment, and the method is suitable for heart data acquisition in a small scale.

In the prior art, the electrocardio sensor has a single function, cannot perform remote large-scale real-time data acquisition, cannot establish corresponding user information in a database, and cannot switch between the electrocardio data and the heart rate data according to the requirements of a user. Therefore, the above problems that the cardiac data cannot be collected in real time in a large scale and that switching between the electrocardiographic data and the heart rate data cannot be performed become difficult problems to be solved by those skilled in the art.

Disclosure of Invention

In view of the above problems in the prior art, an adjustment system based on the parameters of the electrocardiograph sensor is provided for large-scale real-time acquisition of cardiac data and switching between electrocardiographic data and cardiac rate data.

The specific technical scheme is as follows:

the invention provides an adjusting system based on electrocardio sensor parameters, wherein the adjusting system comprises:

the acquisition module is arranged in the electrocardio sensor and is used for acquiring cardiac data of a user wearing the electrocardio sensor;

the detection module is arranged in the electrocardio sensor, connected with the acquisition module and used for detecting the real-time behavior state of a user wearing the electrocardio sensor according to the heart data;

and the switching module is arranged on the electrocardio sensor, connected with the detection module and used for switching the electrocardio sensor between the acquisition of the electrocardio data and the acquisition of the heart rate data according to the real-time behavior state.

Preferably, the detection module includes:

the inertial sensing unit is arranged in the electrocardio sensor and is used for acquiring the resultant acceleration m of the electrocardio sensor in the transverse axis direction and the longitudinal axis direction and the conversion frequency value x of the resultant acceleration m;

and the judging unit is connected with the inertial sensing unit and used for judging the real-time behavior state according to the conversion frequency value x and the resultant acceleration m.

Preferably, when the conversion frequency value x is greater than or equal to a first threshold value y and the resultant acceleration m is greater than or equal to a second threshold value n, the determining unit determines that the real-time behavior state of the user is a motion state;

when the conversion frequency value x is smaller than the first threshold value y and the resultant acceleration m is smaller than the second threshold value n, the determining unit determines that the real-time behavior state of the user is a non-motion state.

Preferably, the switching module includes:

the switching unit is used for switching the electrocardio sensor from collecting the electrocardio data to collecting the heart rate data when the real-time behavior state is the motion state;

and when the real-time behavior state is the non-motion state, switching the acquisition of the heart rate data by the electrocardio sensor to the acquisition of the electrocardio data.

Preferably, the method further comprises the following steps:

the communication module is used for connecting a receiving end with the electrocardio sensor in a communication way;

the matching module is arranged in the receiving end, connected with the communication module and the acquisition module and used for matching the heart data acquired by the electrocardio sensor with user information which is prestored in the receiving end and corresponds to a user wearing the electrocardio sensor, and the heart data comprises heart rate data and electrocardio data.

Preferably, the matching module includes:

and the acquisition unit is used for acquiring the user information of the wearing user of the electrocardio sensor in advance by the receiving end.

The receiving unit is used for receiving the cardiac data acquired by the electrocardio sensor;

and the matching unit is respectively connected with the acquisition unit and the receiving unit and is used for matching the user information of the wearing user corresponding to the electrocardio sensor, which is prestored in the receiving end, with the heart data.

Preferably, a first identification data used for matching with the user information is preset in the electrocardiograph sensor, and the first identification data is used for the receiving end to match with the user information according to the identification data.

Preferably, the first identification data includes one or more of a user identity, a user physical sign parameter, and a user side identity.

Preferably, the user physical sign parameters include one or more of age, gender, weight, and basal heart rate.

Preferably, the electrocardiograph sensor further includes:

the storage module is used for storing the user parameters and the user physical sign parameters of the user;

and the modifying module is respectively connected with the storage module and the communication module and is used for modifying the user parameters and the user physical sign parameters of the user.

The beneficial effects of the above technical scheme are that: the real-time behavior state of the wearing user is detected through the detection module according to the heart data, the electrocardio sensor is switched between the collected electrocardio data and the collected heart rate data through the switching module according to the real-time behavior state, and the heart data of the user can be collected in a large scale in real time.

Drawings

Embodiments of the present invention will now be described more fully hereinafter with reference to the accompanying drawings. The drawings are, however, to be regarded as illustrative and explanatory only and are not restrictive of the scope of the invention.

FIG. 1 is a functional block diagram of an embodiment of the present invention;

FIG. 2 is a block diagram of a detection module of an embodiment of the present invention;

FIG. 3 is a block diagram of a handover module according to an embodiment of the present invention;

FIG. 4 is a block diagram of a matching module according to an embodiment of the invention.

Detailed Description

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

It should be noted that the embodiments and features of the embodiments may be combined with each other without conflict.

The invention is further described with reference to the following drawings and specific examples, which are not intended to be limiting.

The invention provides an adjusting system based on electrocardio sensor parameters, wherein the adjusting system comprises:

the acquisition module 10 is arranged in the electrocardio sensor 1 and is used for acquiring cardiac data of a user wearing the electrocardio sensor 1;

the detection module 11 is arranged in the electrocardio sensor 1, connected with the acquisition module 10 and used for detecting the real-time behavior state of a user wearing the electrocardio sensor according to the heart data;

and the switching module 12 is arranged on the electrocardio sensor 1, connected with the detection module 11 and used for switching the electrocardio sensor 1 between the electrocardio data acquisition and the heart rate data acquisition according to the real-time behavior state.

With the above-mentioned adjustment system, as shown in fig. 1, the acquisition module 10 in the electrocardiograph sensor 1 acquires heart data of a user in advance, and the detection module 11 detects a real-time behavior state of the user wearing the electrocardiograph sensor 1 according to the heart data of the user, where the real-time behavior state includes a motion state and a non-motion state, for example, the motion state may be a real-time behavior state of a user who is "exercise and fitness", and the non-motion state may be a real-time behavior state of a user who is "medical health".

Further, the switching module 12 switches the electrocardiograph sensor 1 between acquiring electrocardiograph data and acquiring heart rate data according to the two real-time behavior states, for example, when the electrocardiograph sensor 1 intelligently judges that the user starts to perform exercise fitness, the electrocardiograph sensor 1 is switched to acquire heart rate data; when the electrocardio sensor 1 intelligently judges that the user is in a non-motion state, the electrocardio sensor 1 is switched to collect heart rate data.

In this embodiment, the real-time behavior state of the user wearing the electrocardiograph is detected by the detection module 11 according to the cardiac data, and the electrocardiograph is switched between the acquired electrocardiograph data and the acquired heart rate data by the switching module 12 according to the real-time behavior state, so that the user wearing the electrocardiograph 1 can acquire the cardiac data of the user in real time and accurately.

In a preferred embodiment, the detection module 11 comprises:

the inertial sensing unit 110 is arranged in the electrocardiograph sensor 1 and is used for acquiring a resultant acceleration m of the electrocardiograph sensor 1 in the horizontal axis direction and the vertical axis direction and a conversion frequency value x of the resultant acceleration m;

and the judging unit 111 is connected to the inertial sensing unit 110 and is used for judging the real-time behavior state according to the conversion frequency value x and the resultant acceleration m.

Specifically, as shown in fig. 2, in the present embodiment, an inertia sensing unit 110 is disposed in an electrocardiograph 1, the inertia sensing unit 110 is a three-axis acceleration sensor, the electrocardiograph 1 and the three-axis acceleration sensor are both disposed on a printed circuit board (not shown in the figure), and the three-axis acceleration sensor is used to obtain a resultant acceleration m in a horizontal axis direction and a vertical axis direction of the electrocardiograph 1 and obtain a conversion frequency value x according to a change of the resultant acceleration m from 0 to a first threshold value n, where the obtained resultant acceleration m is obtained by firstly wearing the electrocardiograph 1 on a body by a user in a manner that a printed circuit board (not shown in the figure) is parallel to a front surface of the body, that is, a vertical axis of the printed circuit board (not shown in the figure) coincides with a vertical axis of the body.

Further, the inertia sensing unit 110 obtains the acceleration mZ of the electrocardiograph sensor 1 in the horizontal axis direction and the acceleration mY of the electrocardiograph sensor 1 in the vertical axis direction, and then calculates the resultant acceleration m of the electrocardiograph sensor 1 in the horizontal axis direction and the vertical axis direction by a formula:

wherein mY represents an acceleration value of the electrocardio sensor in the direction of a longitudinal axis;

mZ represents the acceleration value of the electrocardio sensor in the direction of the transverse axis;

and m represents the total acceleration value of the electrocardio sensor in the longitudinal axis direction and the transverse axis direction.

Further, a conversion frequency value x of the resultant acceleration m is calculated by the resultant acceleration m.

Further, the real-time behavior state is determined by the determining unit 111 according to the above-mentioned conversion frequency value x and resultant acceleration m, and is used for detecting whether the heart data of the user is heart rate data or electrocardiogram data according to the real-time behavior state.

In a preferred embodiment, when the conversion frequency value x is greater than or equal to a first threshold value y, and the resultant acceleration m is greater than or equal to a second threshold value n, the determining unit 111 determines that the real-time behavior state of the user is a motion state;

when the conversion frequency value x is smaller than the first threshold y and the resultant acceleration m is smaller than the second threshold n, the determining unit 111 determines that the real-time behavior state of the user is a non-motion state.

Specifically, when it is determined that the conversion frequency value x is greater than or equal to a first threshold value y and the resultant acceleration m is greater than or equal to a second threshold value n, the determining unit 111 determines that the real-time behavior state of the user is a motion state; when the conversion frequency value x is smaller than the first threshold value y and the resultant acceleration m is smaller than the second threshold value n, the determining unit 111 determines that the real-time behavior state of the user is a non-motion state, so that the electrocardiograph sensor 1 can acquire different heart data according to the real-time behavior state of the user.

In a preferred embodiment, the switching module 12 includes:

the switching unit 120 is used for switching the electrocardio sensor 1 from the electrocardio data acquisition to the heart rate data acquisition when the real-time behavior state is the motion state;

when the real-time behavior state is a non-motion state, the electrocardio sensor 1 is switched from collecting heart rate data to collecting electrocardio data.

Specifically, as shown in fig. 1, the switching module 12 includes a switching unit 120, and when the determining unit 111 determines that the real-time behavior state is the motion state, the electrocardiograph sensor 1 switches from acquiring electrocardiograph data to acquiring heart rate data; when the judging unit 111 judges that the real-time behavior state is the non-motion state, the electrocardiograph sensor 1 is switched from the heart rate data acquisition to the electrocardiograph data acquisition, so that the user can accurately acquire the real-time heart data.

In a preferred embodiment, the method further comprises:

the communication module 2 is used for connecting a receiving end 3 with the electrocardio sensor 1 in a communication way;

the matching module 30 is arranged in the receiving end 3, connected with the communication module 2 and the acquisition module 10, and used for matching the heart data acquired by the electrocardio sensor 1 with the user information which is prestored in the receiving end 3 and corresponds to the user wearing the electrocardio sensor 1, wherein the heart data comprises heart rate data and electrocardio data.

Specifically, as shown in fig. 1, the present invention further includes a communication module 2, which connects the receiving end 3 to the electrocardiograph sensor 1 in a communication manner, where the communication connection manner includes that the electrocardiograph sensor 1 is connected to the receiving end 3 through a connection transfer device (such as a telecommunication base station); or the electrocardio sensor 1 is connected with the receiving end 3 through a local area network (wireless network); or the electrocardio sensor 1 is connected with the receiving end 3 through the connection intelligent terminal; or the electrocardio sensor 1 is connected with the receiving end 3 through Bluetooth so as to activate the electrocardio sensor 1 through the receiving end 3.

Further, the matching unit 30 in the receiving end 3 matches the heart data acquired by the electrocardiograph sensor 1 with the user information, which is prestored in the receiving end 3 and corresponds to the user wearing the electrocardiograph sensor 1, and records and stores the data in the receiving end 3, so that the user identity can be dynamically identified.

In a preferred embodiment, the matching module 30 includes:

and the acquisition unit 300 is used for the receiving terminal 3 to acquire the user information of the user wearing the electrocardio sensor 1 in advance.

A receiving unit 301, configured to receive cardiac data acquired by the electrocardiograph sensor 1;

and the matching unit 302 is respectively connected with the acquisition unit 300 and the receiving unit 301, and is used for matching the user information, which is prestored in the receiving end 3 and corresponds to the user wearing the electrocardio sensor 1, with the heart data.

Specifically, as shown in fig. 4, the matching module 30 includes an acquisition unit 300, a receiving unit 301, and a matching unit 302, where the matching unit 302 matches the cardiac data acquired by the electrocardiograph sensor 1 received by the receiving unit 301 according to user information of a user wearing the electrocardiograph sensor 1 acquired in advance by the acquisition unit 300.

In a preferred embodiment, a first identification data for matching with the user information is preset in the electrocardiograph sensor 1, and the first identification data is used for the receiving terminal 3 to match with the user information according to the identification data.

In this embodiment, a user wearing the electrocardiograph sensor 1 may set first identification data used for matching with user information in the electrocardiograph sensor 1 in advance, where the first identification data includes one or more of a user identity, a user sign parameter, and a user side identity, and the user sign parameter includes one or more of an age, a gender, a weight, and a basic heart rate, so that the receiving end 3 matches with the user information according to the first identification data.

In a preferred embodiment, the ecg sensor 1 further comprises:

a storage module 13, for storing user parameters and user physical sign parameters of the user;

and the modifying module 14 is respectively connected with the storage module 13 and the communication module 2 and is used for modifying the user parameters and the user physical sign parameters of the user.

Specifically, as shown in fig. 1, in this embodiment, the electrocardiograph sensor 1 further includes a storage module 13 and a modification module 14, where the storage module 13 may be used to store the user information and the user physical sign parameters of the user transmitted by the receiving end 3, and the user may also modify the user parameters and the user physical sign parameters of the user through the modification module 14 at any time according to needs, so that the electrocardiograph sensor 1 can effectively complete detection of cardiac data in various situations.

In a preferred embodiment, the electrocardiograph sensor 1 is further preset with second identification data for filtering the real-time behavior state, where the second identification data includes one or more of an activity type, a name and address information, so as to facilitate filtering cardiac data that the user needs to collect.

In a preferred embodiment, a user sends a power on/off instruction and an instruction for switching the type of collected cardiac data to the electrocardiograph sensor 1 worn by the user through the receiving end 3 of the user. Note that the electrocardiograph sensor 1 of the present invention does not include a mechanical switch.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention.

Claims (10)

1. An adjustment system based on electrocardiograph sensor parameters, the adjustment system comprising:

the acquisition module is arranged in the electrocardio sensor and is used for acquiring cardiac data of a user wearing the electrocardio sensor;

the detection module is arranged in the electrocardio sensor, connected with the acquisition module and used for detecting the real-time behavior state of a user wearing the electrocardio sensor according to the heart data;

and the switching module is arranged on the electrocardio sensor, connected with the detection module and used for switching the electrocardio sensor between the acquisition of the electrocardio data and the acquisition of the heart rate data according to the real-time behavior state.

2. The system of claim 1, wherein the detection module comprises:

the inertial sensing unit is arranged in the electrocardio sensor and is used for acquiring the resultant acceleration m of the electrocardio sensor in the transverse axis direction and the longitudinal axis direction and the conversion frequency value x of the resultant acceleration m;

and the judging unit is connected with the inertial sensing unit and used for judging the real-time behavior state according to the conversion frequency value x and the resultant acceleration m.

3. The system of claim 2, wherein when the conversion frequency value x is greater than or equal to a first threshold value y and the resultant acceleration m is greater than or equal to a second threshold value n, the determining unit determines that the real-time behavior state of the user is a motion state;

when the conversion frequency value x is smaller than the first threshold value y and the resultant acceleration m is smaller than the second threshold value n, the determining unit determines that the real-time behavior state of the user is a non-motion state.

4. The system of claim 3, wherein the switching module comprises:

the switching unit is used for switching the electrocardio sensor from collecting the electrocardio data to collecting the heart rate data when the real-time behavior state is the motion state;

and when the real-time behavior state is the non-motion state, switching the acquisition of the heart rate data by the electrocardio sensor to the acquisition of the electrocardio data.

5. The system of claim 1, further comprising:

the communication module is used for connecting a receiving end with the electrocardio sensor in a communication way;

the matching module is arranged in the receiving end, connected with the communication module and the acquisition module and used for matching the heart data acquired by the electrocardio sensor with user information which is prestored in the receiving end and corresponds to a user wearing the electrocardio sensor, and the heart data comprises heart rate data and electrocardio data.

6. The system of claim 5, wherein the matching module comprises:

and the acquisition unit is used for acquiring the user information of the user wearing the electrocardio sensor in advance by the receiving end.

The receiving unit is used for receiving the cardiac data acquired by the electrocardio sensor;

and the matching unit is respectively connected with the acquisition unit and the receiving unit and is used for matching the user information which is prestored in the receiving end and corresponds to the user wearing the electrocardio sensor according to the heart data.

7. The system according to claim 1, wherein a first identification data for matching with the user information is preset in the electrocardiograph sensor, and the receiving end matches with the user information according to the identification data.

8. The system of claim 7, wherein the first identification data comprises one or more of a user identity, a user physical parameter, and a user end identity.

9. The system of claim 8, wherein the user parameters include one or more of age, gender, weight, and basal heart rate.

10. The system of claim 8, wherein the ecg sensor further comprises:

the storage module is used for storing the user parameters and the user physical sign parameters of the user;

and the modifying module is respectively connected with the storage module and the communication module and is used for modifying the user parameters and the user physical sign parameters of the user.

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