CN114366113A - Method and device for measuring electrocardiogram data, electronic equipment and storage equipment - Google Patents

Abstract

The application discloses a method for measuring electrocardiogram data, which comprises the following steps: in response to detecting a triggering operation for triggering presentation of a virtual measurement tool in an electronic electrocardiogram, presenting the virtual measurement tool in the electronic electrocardiogram; in response to detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, determining a target waveform region defined in the electronic electrocardiogram by the virtual measurement tool, showing in the electronic electrocardiogram duration data, voltage data and heart rate data measured by the virtual measurement tool corresponding to the target waveform region. This application can obtain the relevant data of heart electrograph through the virtual measuring tool of show in electronic heart electrograph, need not artifical analysis heart electrograph data, consequently can improve heart electrograph data's analysis efficiency, reduces because of the working strength that artifical analysis heart electrograph data produced.

Description

Method and device for measuring electrocardiogram data, electronic equipment and storage equipment

Technical Field

The application relates to the technical field of computers, in particular to a method and a device for measuring electrocardiogram data, electronic equipment and storage equipment.

Background

Electrocardiographic examination is one of the routine examinations performed by the medical staff at the time of treatment. Currently, after obtaining the electrocardiogram data, doctors need to perform data analysis on each electrocardiogram. Because the electrocardiographic data of each patient is not identical, and in practical application, a doctor needs to analyze a large amount of electrocardiographic data in a short time. Therefore, the method of manually analyzing the electrocardiogram data is not efficient, and consumes a lot of energy and time of doctors, and the work intensity of manually analyzing the electrocardiogram data is very high.

Disclosure of Invention

The embodiment of the application provides a method for measuring electrocardiogram data, so that the analysis efficiency of the electrocardiogram data is improved, and the working intensity caused by manual analysis of the electrocardiogram data is reduced.

The embodiment of the application provides a method for measuring electrocardiogram data, which comprises the following steps:

in response to detecting a triggering operation for triggering presentation of a virtual measurement tool in an electronic electrocardiogram, presenting the virtual measurement tool in the electronic electrocardiogram;

in response to detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, determining a target waveform region defined in the electronic electrocardiogram by the virtual measurement tool, showing in the electronic electrocardiogram duration data, voltage data and heart rate data measured by the virtual measurement tool corresponding to the target waveform region.

Optionally, the responding to the detection of the triggering operation for triggering the presentation of the virtual measurement tool in the electronic electrocardiogram includes: in response to detecting a triggering operation for a presentation component for presenting a virtual measurement tool.

Optionally, the virtual measuring tool comprises a lateral movement fine tuning component for moving at least one movable component of the virtual measuring tool in a lateral direction;

the responsive to detecting movement of at least one movable component for the virtual measurement tool in the electronic electrocardiogram comprises: responsive to detecting a triggering operation for the lateral movement trim component.

Optionally, the virtual measuring tool comprises a longitudinal movement fine tuning component for moving at least one movable component of the virtual measuring tool in a longitudinal direction;

the responsive to detecting movement of at least one movable component for the virtual measurement tool in the electronic electrocardiogram comprises: responsive to detecting a triggering operation for the longitudinal movement trim component.

Optionally, the responding to the detection of the movement of the at least one movable component for the virtual measurement tool in the electronic electrocardiogram comprises:

in response to detecting a movement operation in the electronic electrocardiogram for a left moveable component of the virtual measurement tool;

and/or, in response to detecting a movement operation in the electronic electrocardiogram for a right moveable component of the virtual measurement tool;

and/or, in response to detecting a movement operation in the electronic electrocardiogram for a top movable component of the virtual measurement tool;

and/or, in response to detecting a movement operation in the electronic electrocardiogram for a bottom movable component of the virtual measurement tool.

Optionally, the left movable element, the right movable element, and the top movable element are all rectangular-shaped movable elements, and the bottom movable element includes two symmetrical triangular-shaped movable elements.

Optionally, the determining a target waveform region defined by the virtual measurement tool in the electronic electrocardiogram in response to detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool comprises: in response to detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, a target waveform region defined in the electronic electrocardiogram by a left movable component, a right movable component, a top movable component, and a bottom movable component of the virtual measurement tool is determined.

Optionally, the virtual measurement tool measures duration data corresponding to the target waveform region in the following manner:

obtaining coordinate data of a left movable component of the virtual measurement tool when delineating the target waveform region;

obtaining coordinate data of a right moveable component of the virtual measurement tool when delineating the target waveform region;

obtaining distance data between the left movable assembly and the right movable assembly according to the coordinate data of the left movable assembly and the coordinate data of the right movable assembly;

obtaining waveform walking speed data of the electronic electrocardiogram;

and acquiring duration data corresponding to the target waveform area according to the distance data between the left movable assembly and the right movable assembly and the waveform walking speed data of the electronic electrocardiogram.

Optionally, the left movable assembly and the right movable assembly are both rectangular-shaped movable assemblies;

the obtaining coordinate data of a left movable component of the virtual measurement tool when delineating the target waveform region comprises: obtaining cross-axis coordinate data of a left side of a left movable component of the virtual measurement tool when delineating the target waveform region;

the obtaining coordinate data of a right movable component of the virtual measurement tool when delineating the target waveform region comprises: obtaining cross-axis coordinate data of a left side of a right moveable assembly of the virtual measurement tool when delineating the target waveform region;

the obtaining distance data between the left movable assembly and the right movable assembly from the coordinate data of the left movable assembly and the coordinate data of the right movable assembly includes:

obtaining first distance data between the left side of the left movable assembly and the left side of the right movable assembly according to the cross-axis coordinate data of the left side of the left movable assembly and the cross-axis coordinate data of the left side of the right movable assembly;

obtaining second distance data between a left side of the left movable component and a right side of the left movable component;

obtaining distance data between the left movable assembly and the right movable assembly according to the first distance data and the second distance data.

Optionally, the virtual measurement tool measures voltage data corresponding to the target waveform region in the following manner:

obtaining coordinate data of a top movable component of the virtual measurement tool when delineating the target waveform region;

obtaining coordinate data of a bottom movable component of the virtual measurement tool when delineating the target waveform region;

obtaining distance data between the top movable assembly and the bottom movable assembly from the coordinate data of the top movable assembly and the coordinate data of the bottom movable assembly;

obtaining voltage data corresponding to grids in the electronic electrocardiogram;

obtaining voltage data corresponding to the target waveform region from distance data between the top movable component and the bottom movable component and voltage data corresponding to a grid in the electronic electrocardiogram.

Optionally, the top movable assembly is a rectangular-shaped movable assembly, and the bottom movable assembly is a triangular-shaped movable assembly;

the obtaining coordinate data of a top movable component of the virtual measurement tool when delineating the target waveform region comprises: obtaining longitudinal axis coordinate data of a top side of a top movable assembly of the virtual measurement tool when delineating the target waveform region;

the obtaining coordinate data of a bottom movable component of the virtual measurement tool when delineating the target waveform region comprises: obtaining longitudinal axis coordinate data of a top edge or top end point of a bottom movable component of the virtual measurement tool when delineating the target waveform region;

said obtaining distance data between said top movable assembly and said bottom movable assembly from said coordinate data of said top movable assembly and said coordinate data of said bottom movable assembly, comprising:

obtaining third distance data between the top edge of the top movable component and the top edge or the top end point of the bottom movable component from the longitudinal axis coordinate data of the top edge of the top movable component and the longitudinal axis coordinate data of the top edge or the top end point of the bottom movable component;

obtaining fourth distance data between a top edge of the top movable component and a bottom edge of the top movable component;

obtaining distance data between the top movable assembly and the bottom movable assembly according to the third distance data and the fourth distance data.

Optionally, the virtual measurement tool measures heart rate data corresponding to the target waveform region in the following manner:

acquiring time length data between two adjacent R waves in the target waveform region;

and acquiring heart rate data corresponding to the target waveform area according to the time length data between two adjacent R waves in the target waveform area.

Optionally, the method further includes: adjusting the transparency of the virtual measurement tool in response to detecting a transparency adjustment operation for adjusting the transparency of the virtual measurement tool.

Optionally, the virtual measuring tool comprises a transparency adjustment component for adjusting transparency of the virtual measuring tool;

the response to detecting a transparency adjustment operation to adjust transparency of the virtual measurement tool includes: in response to detecting a triggering operation for the transparency adjustment component.

Optionally, the method further includes: and displaying the amplified target waveform area.

Optionally, the displaying the amplified target waveform region includes: in response to detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, presenting the amplified target waveform region.

Optionally, the virtual measurement tool includes an amplifying component for displaying the amplified target waveform region;

the displaying the amplified target waveform region includes: displaying the amplified target waveform region in response to detecting a trigger operation for the amplifying component.

The embodiment of the present application further provides a measuring device for electrocardiogram data, including: the device comprises a detection unit, a display unit, a determination unit and a virtual measurement tool;

the detection unit is used for sending a request message for requesting to show the virtual measuring tool in the electronic electrocardiogram to the showing unit if a triggering operation for triggering to show the virtual measuring tool in the electronic electrocardiogram is detected;

the presentation unit is used for responding to the request message and presenting the virtual measurement tool in the electronic electrocardiogram;

the virtual measuring tool is used for measuring duration data, voltage data and heart rate data corresponding to a waveform area in the electronic electrocardiogram;

the determination unit is used for determining a target waveform area defined by the virtual measuring tool in the electronic electrocardiogram when the detection unit detects the movement operation of at least one movable component of the virtual measuring tool in the electronic electrocardiogram;

the display unit is further used for displaying duration data, voltage data and heart rate data which are measured by the virtual measuring tool and correspond to the target waveform area in the electronic electrocardiogram.

An embodiment of the present application further provides an electronic device, including:

a processor; and

a memory for storing a computer program which, when the apparatus is powered on and the computer program is run by the processor, performs the method described above.

The embodiment of the application also provides a storage device, wherein the storage device stores a computer program, and the computer program is run by a processor to execute the method.

Compared with the prior art, the embodiment of the application has the following advantages:

the embodiment of the application provides a method for measuring electrocardiogram data, which comprises the following steps: in response to detecting a triggering operation for triggering presentation of a virtual measurement tool in an electronic electrocardiogram, presenting the virtual measurement tool in the electronic electrocardiogram; in response to detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, determining a target waveform region defined in the electronic electrocardiogram by the virtual measurement tool, showing in the electronic electrocardiogram duration data, voltage data and heart rate data measured by the virtual measurement tool corresponding to the target waveform region.

In the embodiment of the application, a virtual measuring tool can be displayed in the electronic electrocardiogram, a target waveform area in the electronic electrocardiogram can be defined through the virtual measuring tool, duration data, voltage data and heart rate data corresponding to the target waveform area can be measured through the virtual measuring tool, and duration data, voltage data and heart rate data corresponding to the target waveform area are displayed. The embodiment of the application can obtain the relevant data of the electrocardiogram through the virtual measuring tool displayed in the electronic electrocardiogram, does not need to manually analyze the electrocardiogram data, and therefore can improve the analysis efficiency of the electrocardiogram data and reduce the working strength generated by manually analyzing the electrocardiogram data.

In addition, in the embodiment of the application, the transparency of the virtual measuring tool is adjustable, and an operator including a doctor can adjust the transparency of the virtual measuring tool according to actual needs, so that the operator including the doctor can conveniently view the electronic electrocardiogram.

In addition, in the embodiment of the present application, the target waveform region defined in the electronic electrocardiogram by the virtual measurement tool may be enlarged, which facilitates the operator including the doctor to view the target waveform region.

Drawings

Fig. 1 is a flowchart of a method for measuring electrocardiogram data according to an embodiment of the present application;

FIG. 2 is a schematic view of a virtual measurement tool provided in an embodiment of the present application;

fig. 3 is a schematic diagram of an apparatus for measuring electrocardiogram data according to an embodiment of the present application.

Detailed Description

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. This application is capable of implementation in many different ways than those herein set forth and of similar import by those skilled in the art without departing from the spirit of this application and is therefore not limited to the specific implementations disclosed below.

The embodiment of the application provides a method for measuring electrocardiogram data, which comprises the following steps: in response to detecting a triggering operation for triggering presentation of a virtual measurement tool in an electronic electrocardiogram, presenting the virtual measurement tool in the electronic electrocardiogram; in response to detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, determining a target waveform region defined in the electronic electrocardiogram by the virtual measurement tool, showing in the electronic electrocardiogram duration data, voltage data and heart rate data measured by the virtual measurement tool corresponding to the target waveform region. The embodiments of the present application will be described in detail below with reference to the accompanying drawings.

The application provides a method for measuring electrocardiogram data, and the specific method steps are shown in figure 1. Specifically, the method comprises the following steps:

step S101: in response to detecting a triggering operation for triggering presentation of a virtual measurement tool in an electronic electrocardiogram, presenting the virtual measurement tool in the electronic electrocardiogram.

As shown in fig. 2, in response to detection of a trigger operation for triggering presentation of a virtual measurement tool in an electronic electrocardiogram, a virtual measurement tool 10 is presented in the electronic electrocardiogram.

Step S102: in response to detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, determining a target waveform region defined in the electronic electrocardiogram by the virtual measurement tool, showing in the electronic electrocardiogram duration data, voltage data and heart rate data measured by the virtual measurement tool corresponding to the target waveform region.

In response to detecting the trigger operation for the presentation component for presenting the virtual measurement tool, is a trigger operation for the presentation component for presenting the virtual measurement tool. As shown in fig. 2, the display components of the virtual measuring tool 10 include two lateral movement fine tuning components 101 of the virtual measuring tool 10, two longitudinal movement fine tuning components 102 of the virtual measuring tool 10, a left movable component 106 of the virtual measuring tool 10, a right movable component 107 of the virtual measuring tool 10, a top movable component 105 of the virtual measuring tool 10, and a bottom movable component 108 of the virtual measuring tool 10. Wherein the left movable assembly 106, the right movable assembly 107 and the top movable assembly 105 are rectangular shaped movable assemblies and the bottom movable assembly 108 comprises two symmetrical triangular shaped movable assemblies.

A lateral movement fine-tuning component 101 for moving the virtual measuring tool 10 in a lateral direction, and a longitudinal movement fine-tuning component 102 for moving the virtual measuring tool 10 in a longitudinal direction. Specifically, as shown in fig. 1, the lateral movement fine adjustment component 101 is a lateral fine adjustment button, and is composed of left and right arrows, and a user can click the left and right arrows as required to achieve lateral fine adjustment; the longitudinal movement fine adjustment component 102 is a longitudinal fine adjustment button, which is composed of an up-down arrow, and a user can click the up-down arrow to achieve fine adjustment in the longitudinal direction according to needs. Millimeter-scale movement of the virtual measuring tool up, down, left and right can be achieved through the fine adjustment buttons.

Optionally, in response to detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, target waveform regions defined in the electronic electrocardiogram by the left movable component 106, the right movable component 107, the top movable component 105 and the bottom movable component 108 of the virtual measurement tool 10 are determined.

The method for measuring the duration data, the voltage data and the heart rate data of the target waveform area defined in the electronic electrocardiogram comprises the following steps:

(1) the virtual measuring tool measures the duration data corresponding to the target waveform region in the following manner:

obtaining coordinate data of the left movable assembly 106 when the virtual measuring tool 10 circumscribes the target waveform region, that is, obtaining the abscissa coordinate data X1 of the left side of the left movable assembly 106 when the virtual measuring tool 10 circumscribes the target waveform region, since the left movable assembly 106 is rectangular in shape;

obtaining coordinate data of the right movable assembly 106 when the virtual measuring tool 10 circumscribes the target waveform region, that is, obtaining the abscissa coordinate data X2 of the left side of the right movable assembly 107 when the virtual measuring tool 10 circumscribes the target waveform region, since the right movable assembly 107 is rectangular in shape;

obtaining first distance data S1 between the left side of the left movable assembly 106 and the left side of the right movable assembly 106 from the left side abscissa coordinate data X1 of the left movable assembly 106 and the left side abscissa coordinate data X2 of the right movable assembly 106, i.e., S1 is X2-X1;

obtaining second distance data S2 between the left side of the left movable assembly 106 and the right side of the left movable assembly 106;

obtaining distance data S between the left movable assembly 106 and the right movable assembly 107 according to the first distance data S1 and the second distance data S2, i.e., S1-S2-S1- (X2-X1);

obtaining waveform walking speed data V of the electronic electrocardiogram;

the duration data T corresponding to the target waveform region is obtained from the distance data S between the left movable assembly 106 and the right movable assembly 107 and the waveform walking speed data V of the electronic electrocardiogram.

Specifically, the waveform walking speed data V of the electronic electrocardiogram is 25mm/s, and one small grid of the electronic electrocardiogram is 1mm, namely: 0.04 s. One large cell is 5 small cells, i.e. 0.2 s. When the virtual measuring tool 10 moves in the lateral direction, the distance data S in mm between the left movable member 106 and the right movable member 107 is calculated, and the time length data T of the target waveform region is S/V, which is shown in the upper left time data display window 109 of the virtual measuring tool 10, and 1270ms in fig. 2 is schematic time length data.

(2) The virtual measurement tool measures the voltage data U corresponding to the target waveform region in the following manner:

coordinate data Y1 of the vertical axis coordinate data of the top side of the top movable assembly 105, coordinate data Y2 of the vertical axis coordinate data of the top side or top end point of the bottom movable assembly 108, voltage data U1 corresponding to the grid in the electronic electrocardiogram,

obtaining third distance data L1, i.e., L1 — Y2-Y1, between the top edge of the top movable assembly 105 and the top edge or top end point of the bottom movable assembly 108;

obtaining fourth distance data L2 between the top edge of top movable assembly 105 and the bottom edge of top movable assembly 105;

obtaining distance data L between the top movable assembly 105 and the bottom movable assembly 108, i.e., L1-L2-L1- (Y2-Y1), from the third distance data L1 and the fourth distance data L2;

from the distance data L between the top movable assembly 105 and the bottom movable assembly 108 and the voltage data U1 corresponding to the grid in the electronic electrocardiogram, voltage data U corresponding to the target waveform region is obtained.

Specifically, the longitudinal small grid of the electronic electrocardiogram is U1 ═ 0.1mV, i.e. 1mm represents 0.1mV, and the longitudinal large grid represents 0.5mV, i.e. 0.5 mm. When the virtual measuring tool 10 moves in the longitudinal direction, the distance data L in mm between the top movable element 105 and the bottom movable element 108 is calculated, and the voltage data U ═ L × U1 of the target waveform region is shown in the voltage data display window 110 at the lower right of the virtual measuring tool 10, where 2.33mV in fig. 2 is a schematic voltage data.

(3) The virtual measurement tool measures heart rate data corresponding to the target waveform region as follows:

acquiring time length data R-R between two adjacent R waves in a target waveform region;

according to the time length data R-R between two adjacent R waves in the target waveform region, the heart rate data corresponding to the target waveform region, namely the heart rate is 60/R-R, is obtained according to a specific formula of the heart rate calculation, and is shown in the upper right heart rate data display window 111 of the virtual measurement tool 10, and 47bpm in fig. 2 is schematic heart rate data.

The virtual measurement tool further includes a transparency adjustment component 103 for adjusting the transparency of the virtual measurement tool, which is located at the rightmost side of the virtual measurement tool 10, the transparency adjustment component 103 setting the percentage of transparency of the virtual measurement tool 10 in a manner of dragging a progress bar. By adjusting the transparency of the virtual measuring tool 10, the waveform of the electrocardiogram at the bottom of the virtual measuring tool 10 can be displayed more clearly.

The virtual measuring tool further comprises an amplifying assembly 104 for displaying the amplified target waveform region, the amplifying assembly is positioned at the upper right of the virtual measuring tool 10, and the target waveform region is synchronously amplified by 4 times in a rectangular frame mode, so that the target waveform region is displayed to a diagnostician more intuitively, and the electrocardiogram detection and analysis efficiency of the diagnostician is greatly improved.

The embodiment of the application also provides a measuring device of electrocardiogram data. As shown in fig. 3, the measuring apparatus includes: the detection unit 201, the presentation unit 202, the determination unit 203 and the virtual measurement tool 10;

the detecting unit 201 is configured to send a request message for requesting to present the virtual measuring tool 10 in the electronic electrocardiogram to the presenting unit 202 if a triggering operation for triggering presentation of the virtual measuring tool 10 in the electronic electrocardiogram is detected;

the presentation unit 202 is configured to present the virtual measurement tool 10 in the electronic electrocardiogram in response to the request message;

the virtual measuring tool 10 is used for measuring duration data, voltage data and heart rate data corresponding to a waveform area in the electronic electrocardiogram;

the determination unit 203 is configured to determine a target waveform region defined in the electronic electrocardiogram by the virtual measuring tool 10 when the detection unit 201 detects a moving operation in the electronic electrocardiogram for at least one movable component of the virtual measuring tool 10;

the display unit 202 is further configured to display the duration data, the voltage data and the heart rate data corresponding to the target waveform area measured by the virtual measurement tool 10 in the electronic electrocardiogram.

Optionally, the detecting a triggering operation for triggering presentation of a virtual measurement tool in an electronic electrocardiogram includes: a trigger operation is detected for a presentation component for presenting a virtual measurement tool.

Optionally, the virtual measuring tool 10 comprises a lateral movement fine adjustment assembly for laterally moving at least one movable assembly of the virtual measuring tool;

detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, comprising: a trigger operation for the lateral movement trim component is detected.

Optionally, the virtual measuring tool 10 comprises a longitudinal movement fine tuning component for moving at least one movable component of the virtual measuring tool in a longitudinal direction;

the detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool comprises: a trigger operation for the longitudinal movement trim component is detected.

Optionally, the detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool comprises:

detecting a movement operation in the electronic electrocardiogram for a left movable component of the virtual measuring tool 10;

and/or, detecting a movement operation in the electronic electrocardiogram for the right movable component of the virtual measuring tool 10;

and/or, detecting a movement operation in the electronic electrocardiogram for the top movable component of the virtual measurement tool 10;

and/or detecting a movement operation in the electronic electrocardiogram for the bottom movable component of the virtual measurement tool 10.

Optionally, the left movable element, the right movable element, and the top movable element are all rectangular-shaped movable elements, and the bottom movable element includes two symmetrical triangular-shaped movable elements.

Optionally, the detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, determining a target waveform region defined in the electronic electrocardiogram by the virtual measurement tool, includes: detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, determining a target waveform region defined in the electronic electrocardiogram by a left movable component, a right movable component, a top movable component, and a bottom movable component of the virtual measurement tool.

Optionally, the virtual measurement tool measures duration data corresponding to the target waveform region in the following manner:

obtaining coordinate data of a left movable component of the virtual measurement tool 10 when circumscribing the target waveform region;

obtaining coordinate data of the right movable component of the virtual measurement tool 10 when circumscribing the target waveform region;

obtaining distance data between the left movable assembly and the right movable assembly according to the coordinate data of the left movable assembly and the coordinate data of the right movable assembly;

obtaining waveform walking speed data of the electronic electrocardiogram;

and acquiring duration data corresponding to the target waveform area according to the distance data between the left movable assembly and the right movable assembly and the waveform walking speed data of the electronic electrocardiogram.

Optionally, the left movable assembly and the right movable assembly are both rectangular-shaped movable assemblies;

the obtaining coordinate data of a left movable component of the virtual measurement tool when delineating the target waveform region comprises: obtaining cross-axis coordinate data of a left side of a left movable component of the virtual measuring tool 10 when circumscribing the target waveform region;

the obtaining coordinate data of a right movable component of the virtual measurement tool when delineating the target waveform region comprises: obtaining cross-axis coordinate data of a left side of the right movable assembly of the virtual measuring tool 10 when circumscribing the target waveform region;

the obtaining distance data between the left movable assembly and the right movable assembly from the coordinate data of the left movable assembly and the coordinate data of the right movable assembly includes:

obtaining first distance data between the left side of the left movable assembly and the left side of the right movable assembly according to the cross-axis coordinate data of the left side of the left movable assembly and the cross-axis coordinate data of the left side of the right movable assembly;

obtaining second distance data between a left side of the left movable component and a right side of the left movable component;

obtaining distance data between the left movable assembly and the right movable assembly according to the first distance data and the second distance data.

The virtual measurement tool measures voltage data corresponding to the target waveform region in the following manner:

obtaining coordinate data of a top movable component of the virtual measurement tool 10 when circumscribing the target waveform region;

obtaining coordinate data of a bottom movable component of the virtual measurement tool 10 when circumscribing the target waveform region;

obtaining distance data between the top movable assembly and the bottom movable assembly from the coordinate data of the top movable assembly and the coordinate data of the bottom movable assembly;

obtaining voltage data corresponding to grids in the electronic electrocardiogram;

obtaining voltage data corresponding to the target waveform region from distance data between the top movable component and the bottom movable component and voltage data corresponding to a grid in the electronic electrocardiogram.

Optionally, the top movable assembly is a rectangular-shaped movable assembly, and the bottom movable assembly is a triangular-shaped movable assembly;

the obtaining coordinate data of a top movable component of the virtual measurement tool when delineating the target waveform region comprises: obtaining longitudinal axis coordinate data of a top side of the top movable assembly of the virtual measurement tool 10 when circumscribing the target waveform region;

the obtaining coordinate data of a bottom movable component of the virtual measurement tool when delineating the target waveform region comprises: obtaining longitudinal axis coordinate data of a top edge or top end point of the bottom movable component of the virtual measurement tool 10 when circumscribing the target waveform region;

said obtaining distance data between said top movable assembly and said bottom movable assembly from said coordinate data of said top movable assembly and said coordinate data of said bottom movable assembly, comprising:

obtaining third distance data between the top edge of the top movable component and the top edge or the top end point of the bottom movable component from the longitudinal axis coordinate data of the top edge of the top movable component and the longitudinal axis coordinate data of the top edge or the top end point of the bottom movable component;

obtaining fourth distance data between a top edge of the top movable component and a bottom edge of the top movable component;

obtaining distance data between the top movable assembly and the bottom movable assembly according to the third distance data and the fourth distance data.

Optionally, the virtual measurement tool measures heart rate data corresponding to the target waveform region in the following manner:

acquiring time length data between two adjacent R waves in the target waveform region;

and acquiring heart rate data corresponding to the target waveform area according to the time length data between two adjacent R waves in the target waveform area.

Optionally, the method further includes: detecting a transparency adjustment operation for adjusting the transparency of the virtual measurement tool, and adjusting the transparency of the virtual measurement tool.

Optionally, the virtual measuring tool 10 includes a transparency adjustment component for adjusting transparency of the virtual measuring tool;

the detecting a transparency adjustment operation for adjusting transparency of the virtual measurement tool includes: a trigger operation for the transparency adjustment component is detected.

Optionally, the method further includes: and displaying the amplified target waveform area.

Optionally, the displaying the amplified target waveform region includes: detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, showing the target waveform region after amplification.

Optionally, the virtual measurement tool 10 includes an amplifying component for displaying the amplified target waveform region;

the displaying the amplified target waveform region includes: and detecting a trigger operation aiming at the amplifying component, and displaying the amplified target waveform area.

An embodiment of the present application further provides an electronic device, including:

a processor; and

a memory for storing a computer program which, when the apparatus is powered on and the computer program is run by the processor, performs the method described above.

The embodiment of the application also provides a storage device, wherein the storage device stores a computer program, and the computer program is run by a processor to execute the method.

Although the present application has been described with reference to the preferred embodiments, it is not intended to limit the present application, and those skilled in the art can make variations and modifications without departing from the spirit and scope of the present application, therefore, the scope of the present application should be determined by the claims that follow.

Claims (10)

1. A method for measuring electrocardiographic data, comprising:

in response to detecting a triggering operation for triggering presentation of a virtual measurement tool in an electronic electrocardiogram, presenting the virtual measurement tool in the electronic electrocardiogram;

in response to detecting a movement operation in the electronic electrocardiogram for at least one movable component of the virtual measurement tool, determining a target waveform region defined in the electronic electrocardiogram by the virtual measurement tool, showing in the electronic electrocardiogram duration data, voltage data and heart rate data measured by the virtual measurement tool corresponding to the target waveform region.

2. The method of measuring electrocardiographic data according to claim 1 wherein said responding to detection of movement of at least one movable component of said virtual measurement tool in said electronic electrocardiogram comprises:

in response to detecting a movement operation in the electronic electrocardiogram for a left moveable component of the virtual measurement tool;

and/or, in response to detecting a movement operation in the electronic electrocardiogram for a right moveable component of the virtual measurement tool;

and/or, in response to detecting a movement operation in the electronic electrocardiogram for a top movable component of the virtual measurement tool;

and/or, in response to detecting a movement operation in the electronic electrocardiogram for a bottom movable component of the virtual measurement tool.

3. The method for measuring electrocardiographic data according to claim 2, wherein the virtual measuring means measures the time length data corresponding to the target waveform region in the following manner:

obtaining coordinate data of a left movable component of the virtual measurement tool when delineating the target waveform region;

obtaining coordinate data of a right moveable component of the virtual measurement tool when delineating the target waveform region;

obtaining distance data between the left movable assembly and the right movable assembly according to the coordinate data of the left movable assembly and the coordinate data of the right movable assembly;

obtaining waveform walking speed data of the electronic electrocardiogram;

and acquiring duration data corresponding to the target waveform area according to the distance data between the left movable assembly and the right movable assembly and the waveform walking speed data of the electronic electrocardiogram.

4. The method for measuring electrocardiographic data according to claim 2, wherein the virtual measuring means measures voltage data corresponding to the target waveform region in the following manner:

obtaining coordinate data of a top movable component of the virtual measurement tool when delineating the target waveform region;

obtaining coordinate data of a bottom movable component of the virtual measurement tool when delineating the target waveform region;

obtaining distance data between the top movable assembly and the bottom movable assembly from the coordinate data of the top movable assembly and the coordinate data of the bottom movable assembly;

obtaining voltage data corresponding to grids in the electronic electrocardiogram;

obtaining voltage data corresponding to the target waveform region from distance data between the top movable component and the bottom movable component and voltage data corresponding to a grid in the electronic electrocardiogram.

5. The method of measuring electrocardiographic data according to claim 1, wherein the virtual measurement means measures heart rate data corresponding to the target waveform region in the following manner:

acquiring time length data between two adjacent R waves in the target waveform region;

and acquiring heart rate data corresponding to the target waveform area according to the time length data between two adjacent R waves in the target waveform area.

6. The method for measuring electrocardiographic data according to claim 1, further comprising: adjusting the transparency of the virtual measurement tool in response to detecting a transparency adjustment operation for adjusting the transparency of the virtual measurement tool.

7. The method for measuring electrocardiographic data according to claim 1, further comprising: and displaying the amplified target waveform area.

8. An apparatus for measuring electrocardiographic data, comprising: the device comprises a detection unit, a display unit, a determination unit and a virtual measurement tool;

the detection unit is used for sending a request message for requesting to show the virtual measuring tool in the electronic electrocardiogram to the showing unit if a triggering operation for triggering to show the virtual measuring tool in the electronic electrocardiogram is detected;

the presentation unit is used for responding to the request message and presenting the virtual measurement tool in the electronic electrocardiogram;

the virtual measuring tool is used for measuring duration data, voltage data and heart rate data corresponding to a waveform area in the electronic electrocardiogram;

the determination unit is used for determining a target waveform area defined by the virtual measuring tool in the electronic electrocardiogram when the detection unit detects the movement operation of at least one movable component of the virtual measuring tool in the electronic electrocardiogram;

the display unit is further used for displaying duration data, voltage data and heart rate data which are measured by the virtual measuring tool and correspond to the target waveform area in the electronic electrocardiogram.

9. An electronic device, comprising:

a processor; and

a memory for storing a computer program which, when the apparatus is powered on and the computer program is run by the processor, performs the method of claims 1-8.

10. A storage device, characterized in that the storage device stores a computer program which is executed by a processor for performing the method according to claims 1-8.

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