CN110916649A - Processing device, processing method and detection device for long-range electrocardiogram scatter diagram - Google Patents
Processing device, processing method and detection device for long-range electrocardiogram scatter diagram Download PDFInfo
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Abstract
The invention discloses a processing device, a processing method and a detection device of a long-range electrocardiogram scatter diagram, wherein the processing device comprises: the region dividing module is used for acquiring a target long-range electrocardio scattergram and dividing the region of the target long-range electrocardio scattergram; the boundary acquisition module is used for acquiring boundary points corresponding to the areas according to the area attributes and the heartbeat detection data; and the analysis module is used for obtaining the region analysis result of the target long-range electrocardio scatter diagram according to the boundary points. According to the method, the theme and the area division rule of the long-range electrocardio scattergram are preset, so that corresponding area division can be carried out according to the selected theme when the target long-range electrocardio scattergram is analyzed, and the analysis difficulty and the working strength of medical personnel are reduced; the boundary points of the area are obtained according to the area attribute and the heart beat detection data, so that the method can adapt to different long-range electrocardiogram detection data, and the analysis accuracy and definition of the long-range electrocardiogram scatter diagram output by the electrocardiogram detection device are improved.
Description
Technical Field
The invention relates to the technical field of electrocardiogram data analysis, in particular to a processing device, a processing method and a detection device for a long-range electrocardiogram scatter diagram.
Background
The long-range electrocardiogram scattergram is characterized in that an electrocardiogram detection device is used for extracting recorded human heart activity signals into digital signals, the rhythm of heart pulsation is expressed on a two-dimensional plane rectangular coordinate system in the form of a scattergram, and then the arrhythmia condition of a detected person is analyzed according to the typical distribution characteristics of the scattergram on clinic. However, the long-range electrocardiogram scatter diagram output by the electrocardiogram detection device in the prior art has a large data amount, is not divided into areas, and has high manual analysis difficulty and working strength.
Accordingly, the prior art is yet to be improved and developed.
Disclosure of Invention
The technical problem to be solved by the present invention is to provide a processing device, a processing method and a detection device for a long-range electrocardiographic scattergram, aiming at solving the problems that the conventional electrocardiographic detection device outputs a large amount of long-range electrocardiographic scattergram data, does not perform region division, and has high difficulty in manual analysis and high working strength.
The technical scheme adopted by the invention for solving the technical problem is as follows:
a device for processing a long range cardiac scattergram, the device comprising:
the region division module is used for acquiring a target long-range electrocardiogram scatter diagram and carrying out region division on the target long-range electrocardiogram scatter diagram according to a region division rule corresponding to the theme of the target long-range electrocardiogram scatter diagram;
the boundary acquisition module is used for acquiring boundary points corresponding to the region according to the region attribute of the region and the heartbeat detection data corresponding to the target long-range electrocardiogram scattergram;
and the analysis module is used for obtaining the region analysis result of the target long-range electrocardiogram scatter diagram according to the boundary points.
The processing device of the long-range electrocardiogram scatter diagram comprises:
the system comprises a presetting module and a processing module, wherein the presetting module is used for presetting the theme of the long-range electrocardio scatter diagram and the area division rule corresponding to the long-range electrocardio scatter diagram with different themes and setting the area attribute corresponding to the area.
The processing device of the long-range electrocardiogram scatter diagram comprises an area dividing module, a processing module and a processing module, wherein the area dividing module specifically comprises:
the theme acquisition unit is used for acquiring a target long-range electrocardiogram scatter diagram and acquiring a theme of the target long-range electrocardiogram scatter diagram from a preset theme of the long-range electrocardiogram scatter diagram;
and the region dividing unit is used for performing region division on the target long-range electrocardio scatter diagram according to a region dividing rule corresponding to the theme of the target long-range electrocardio scatter diagram.
The processing device of the long-range electrocardiogram scatter diagram is characterized in that the region attributes comprise shape features, boundary features and heart beat types; the shape features include an axis type, a circle type, a triangle type, a rectangle type, and a polygon type.
The processing device of the long-range electrocardiogram scatter diagram comprises a boundary acquisition module, a processing module and a processing module, wherein the boundary acquisition module specifically comprises:
a first boundary acquisition unit, configured to, when the shape feature of the region is an axis type, take a coordinate point in the region including the largest number of heartbeats as a center point, start acquiring, from the center point, coordinate points on the axis on both sides of the center point corresponding to heartbeats not conforming to the heart beat type of the region as an end point, and start acquiring, from the end point, coordinate points on both sides of the end point corresponding to coordinate points perpendicular to the axis direction corresponding to heart beats not conforming to the heart beat type of the region as boundary points of the region;
a second boundary acquisition unit, configured to, when the shape feature of the region is a circular type, sequentially circle a circular region with increasing radii by using a coordinate point, as a dot, in the region that includes the largest number of heartbeats, and when all heartbeats that conform to the heart beat type of the region are included in the circular region, take a boundary point of the circular region as a boundary point corresponding to the region;
and a third boundary acquiring unit, configured to, when the shape feature of the region is a triangle type, a rectangle type, or a polygon type, take a coordinate point in the region that includes the largest number of heart beats as a center point, and acquire, from the center point, a coordinate point corresponding to a coordinate point in a vertical direction of each side of the region, where a heart beat does not conform to the heart beat type of the region, as a boundary point corresponding to the region.
The processing device of the long-range electrocardiogram scatter diagram comprises:
the highlight display module is used for acquiring a region where a target position is located and highlighting the region where the target position is located;
and the data processing module is used for acquiring the heart beat of the area where the target position is located and performing preset operation on the heart beat of the area where the target position is located.
The processing method of the long-range electrocardiogram scattergram of the processing device of the long-range electrocardiogram scattergram comprises the following steps:
acquiring a target long-range electrocardiogram scattergram, and performing region division on the target long-range electrocardiogram scattergram according to a region division rule corresponding to the theme of the target long-range electrocardiogram scattergram;
acquiring boundary points corresponding to the region according to the region attribute of the region and heartbeat detection data corresponding to the target long-range electrocardiogram scattergram;
and obtaining the region analysis result of the target long-range electrocardiogram scatter diagram according to the boundary points.
The processing method of the long-range electrocardiogram scattergram comprises the following steps of obtaining a target long-range electrocardiogram scattergram, and carrying out region division on the target long-range electrocardiogram scattergram according to a region division rule corresponding to a theme of the target long-range electrocardiogram scattergram:
the method comprises the steps of presetting a theme of a long-range electrocardiogram scatter diagram and an area division rule corresponding to the long-range electrocardiogram scatter diagram with different themes, and setting an area attribute corresponding to the area.
The processing method of the long-range electrocardiogram scattergram comprises the following steps of obtaining a target long-range electrocardiogram scattergram, and carrying out region division on the target long-range electrocardiogram scattergram according to a region division rule corresponding to a theme of the target long-range electrocardiogram scattergram, wherein the step of obtaining the target long-range electrocardiogram scattergram further comprises the following steps:
acquiring a target long-range electrocardiogram scatter diagram, and acquiring the theme of the target long-range electrocardiogram scatter diagram from the preset theme of the long-range electrocardiogram scatter diagram;
carrying out region division on the target long-range electrocardio scattergram according to a region division rule corresponding to the theme of the target long-range electrocardio scattergram;
the region attributes include shape features, boundary features, and heart beat type; the shape features include an axis type, a circle type, a triangle type, a rectangle type, and a polygon type;
the step of acquiring boundary points corresponding to the region according to the region attribute of the region and the heart beat detection data corresponding to the target long-range electrocardiogram scattergram specifically includes:
when the shape feature of the area is an axis type, taking a coordinate point containing the largest heart beat number in the area as a central point, acquiring coordinate points, corresponding to the coordinate points on the axis on two sides of the central point, of heart beats not conforming to the heart beat type of the area from the central point as end points, and acquiring coordinate points, corresponding to the coordinate points on two sides of the end points perpendicular to the axis direction, of heart beats not conforming to the heart beat type of the area from the end points as boundary points of the area;
when the shape feature of the area is a circular type, a coordinate point containing the largest number of heart beats in the area is taken as a circular point, a circular area is defined by increasing radiuses in sequence, and when all heart beats conforming to the heart beat type of the area are contained in the circular area, the boundary point of the circular area is taken as the boundary point corresponding to the area;
when the shape feature of the area is a triangle type, a rectangle type or a polygon type, taking a coordinate point containing the largest number of heart beats in the area as a central point, and acquiring a coordinate point, corresponding to a coordinate point in the vertical direction of each side of the area, of which the heart beats do not conform to the heart beat type of the area from the central point as a boundary point corresponding to the area.
An electrocardiogram detection device comprises a processor, a communication bus and a memory;
the memory is stored with a long-range electrocardio scattergram processing program which can be executed by the processor;
the communication bus realizes connection communication between the processor and the memory;
the memory stores a processing device provided with the long-range electrocardiogram scatter diagram, and the processor realizes the processing method steps of the long-range electrocardiogram scatter diagram when executing the long-range electrocardiogram scatter diagram processing program.
The invention has the beneficial effects that: by presetting the theme of the long-range electrocardio scattergram and the corresponding area division rule thereof, the target long-range electrocardio scattergram can be correspondingly divided according to the selected theme when being analyzed, so that the analysis difficulty and the working strength of medical personnel are reduced; boundary points of the regions are obtained according to the region attributes and the heart beat detection data, and a final region analysis result is obtained according to the boundary points, so that the method can adapt to different long-range electrocardiogram detection data, and the analysis accuracy and definition of the long-range electrocardiogram scattergram output by the electrocardiogram detection device are improved.
Drawings
FIG. 1 is a functional schematic diagram of a preferred embodiment of a processing apparatus for a long-range cardiac scattergram according to the present invention;
FIG. 2 is a regional distribution diagram corresponding to a long-range ECG scattergram of the 'room early editing' theme provided by the invention;
FIG. 3 is a region distribution diagram corresponding to different shape features and different boundary features provided by the present invention;
FIG. 4 is a flowchart of a method for processing a long-range cardiac scattergram according to a preferred embodiment of the present invention;
fig. 5 is a functional schematic diagram of an electrocardiogram detection device provided by the invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention clearer and clearer, the present invention is further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.
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. The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses. 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.
The invention provides a processing device of a long-range electrocardiogram scatter diagram, which aims to solve the problems that the data volume of the long-range electrocardiogram scatter diagram output by a conventional electrocardiogram detection device is large, the region division is not performed, and the manual analysis difficulty and the working strength are high. As shown in fig. 1, the apparatus includes a region dividing module 110, a boundary acquiring module 120, and an analyzing module 130. The region division module 110 is configured to obtain a target long-range electrocardiograph scattergram, and perform region division on the target long-range electrocardiograph scattergram according to a region division rule corresponding to a theme of the target long-range electrocardiograph scattergram. The boundary acquisition module 120 is configured to acquire boundary points corresponding to the region according to the region attribute of the region and the heartbeat detection data corresponding to the target long-range electrocardiograph scattergram. The analysis module 130 is configured to obtain an area analysis result of the target long-range electrocardiograph scattergram according to the boundary point.
In specific implementation, because the existing long-range electrocardiograph scattergram has a large data amount and is difficult to manually analyze and high in working strength, in this embodiment, after the electrocardiograph detection device acquires heart beat detection data, the region division module 110 makes the heart beat detection data into a scattergram to obtain a target long-range electrocardiograph scattergram to be processed, and performs region division on the target long-range electrocardiograph scattergram according to a region division rule corresponding to a theme of the target long-range electrocardiograph scattergram, which is a problem of the target long-range electrocardiograph scattergram to be analyzed, so as to obtain a preliminary region division result of the target long-range electrocardiograph scattergram. Because the scatter positions and the boundaries of the regions of different long-range electrocardiograph scattergrams are different, in order to better analyze the target long-range electrocardiograph scattergram, the boundary acquisition module 120 further acquires the boundary points corresponding to the regions according to the region attributes obtained after the region division module 110 preliminarily divides the regions and the heartbeat detection data corresponding to the target long-range electrocardiograph scattergram. Finally, the analysis module 130 obtains an area analysis result of the target long-range electrocardiograph scattergram according to the boundary point corresponding to the area obtained by the boundary obtaining module 120.
In a specific embodiment, the device further includes a presetting module for presetting a theme of the long-range electrocardiographic scattergram and a region division rule corresponding to the long-range electrocardiographic scattergram of different themes, and setting a region attribute corresponding to the region. In specific implementation, different long-range electrocardiogram scatter diagrams focus on analyzing different problems, and the long-range electrocardiogram scatter diagrams with different problems have different regional characteristics. In order to reduce the analysis difficulty and the working strength of the long-range electrocardiogram scattergram and improve the analysis efficiency of medical care personnel, the theme of the long-range electrocardiogram scattergram and the region division rule corresponding to the long-range electrocardiogram scattergram with different themes are preset by the preset module, and the region attribute corresponding to each region is set. In a specific embodiment, the presetting module obtains the region division rules corresponding to the long-range electrocardiogram scattergrams of different themes by setting a plurality of themes for a square scattergram region, performing region division for the square scattergram region of each theme and setting the region attribute corresponding to each region, so that the region division module 110 performs preliminary region division for the obtained target long-range electrocardiogram scattergram.
In a specific embodiment, the theme is a set of areas combining a plurality of areas to solve a certain kind of problem, and one theme may include a plurality of areas, and the areas may overlap with each other, but not allow complete overlap. The names of the topics are generally named for solving the problem, such as "room morning", "artifact", but may be arbitrarily named, such as "artifact 4 partitions", etc., and the number of topics is not limited. The region division rules corresponding to different subjects are usually determined according to known rhythm distribution regions and regions customized by doctors, and the regions are also preset with region attributes, wherein the region attributes comprise shape features, boundary features and heart beat types. Wherein the shape features include an axis type, a circle type, a triangle type, a rectangle type, and a polygon type. The heart beat types include normal (N), ventricular premature (V), supraventricular premature (S), artifact and unknown (a), Bundle Branch Block (BBB), atrial fibrillation and pacing. As shown in fig. 2, the long-range electrocardiograph scattergram with the "ventricular premature editing" theme is divided into four regions, i.e., a ventricular premature beat region, a dominant rhythm region, a post-premature beat region, and a pre-premature beat region, as can be seen from fig. 2.
In a specific embodiment, the boundary features comprise fixed boundary features and unfixed boundary features, the regions with the unfixed boundary features are unfixed, the range of the regions is unfixed, and after the long-range electrocardiogram scatter diagram is obtained, the boundaries of the regions are determined according to the shape features of the regions and heartbeat detection data corresponding to the target long-range electrocardiogram scatter diagram; the region with fixed boundary features has a fixed region range, and as shown in fig. 3, the region distribution diagram corresponding to different shape features and different boundary features is shown, where the solid line is the fixed boundary feature region and the dotted line is the unfixed boundary feature region. In the foregoing steps, it is mentioned that the scatter positions and the area boundaries of the long-range electrocardiographic scattergrams of different patients are different, the long-range electrocardiographic scattergrams of different patients can be automatically adapted by setting the area with unfixed boundary characteristics, and the area with the fixed boundary characteristics is suitable for the area which cannot be automatically searched and the area with a very determined range.
In a specific embodiment, the area dividing module 110 specifically includes a theme obtaining unit and an area dividing unit. The theme acquisition unit is used for acquiring a target long-range electrocardiogram scatter diagram and acquiring a theme of the target long-range electrocardiogram scatter diagram from a preset theme of the long-range electrocardiogram scatter diagram. The region division unit is used for carrying out region division on the target long-range electrocardio scattergram according to a region division rule corresponding to the theme of the target long-range electrocardio scattergram. In specific implementation, after the theme obtaining unit obtains the target long-range electrocardiogram scattergram, a theme can be obtained for the target long-range electrocardiogram scattergram from preset themes of the long-range electrocardiogram scattergram according to a problem to be analyzed. Because the preset module is preset with the region division rules corresponding to the long-range electrocardiogram scattergram with different themes, the region division unit can carry out region division corresponding to the theme on the target long-range electrocardiogram scattergram according to the different themes acquired by the theme acquisition unit, so that a preliminary region analysis result of the long-range electrocardiogram scattergram can be quickly obtained.
In a specific embodiment, the boundary acquisition module 120 includes a first boundary acquisition unit, a second boundary acquisition unit, and a third boundary acquisition unit. The first boundary acquisition unit is used for taking a coordinate point containing the largest number of heart beats in the area as a central point when the shape feature of the area is an axis type, acquiring coordinate points, corresponding to the coordinate points on the axis on two sides of the central point, of heart beats not conforming to the heart beat type of the area from the central point as end points, and acquiring coordinate points, corresponding to the coordinate points on two sides of the end points perpendicular to the axis direction, of heart beats not conforming to the heart beat type of the area from the end points as boundary points of the area. The second boundary acquisition unit is used for sequentially encircling a circular region with increasing radius by taking a coordinate point containing the largest number of heart beats in the region as a circular point when the shape feature of the region is a circular type, and taking the boundary point of the circular region as a boundary point corresponding to the region when all heart beats conforming to the heart beat type of the region are contained in the circular region. The third boundary acquiring unit is configured to, when the shape feature of the region is a triangle type, a rectangle type, or a polygon type, take a coordinate point in the region that includes the largest number of heart beats as a center point, and acquire, from the center point, a coordinate point corresponding to a coordinate point in a vertical direction of each side of the region where a heart beat does not conform to the heart beat type of the region as a boundary point corresponding to the region.
In specific implementation, the boundary obtaining module 120 further includes a feature determining unit, where the feature determining unit is configured to determine whether the shape feature of the region is an axis type, a circular type, a triangular type, a rectangular type, or a polygonal type. When the shape feature of the region is judged to be the axis type, acquiring boundary points of the region through a first boundary unit; when the shape feature of the region is judged to be a circular type, acquiring boundary points of the region through a second boundary acquisition unit; and when the shape characteristic of the region is judged to be a triangle type, a rectangle type or a polygon type, acquiring the boundary point of the region through a third boundary acquisition unit.
In a specific embodiment, the apparatus further comprises a highlighting module and a data processing module. The highlight display module is used for acquiring a region where a target position is located and highlighting the region where the target position is located. The data processing module is used for acquiring the heart beat of the area where the target position is located and carrying out preset operation on the heart beat of the area where the target position is located. In specific implementation, when a user needs to analyze a certain position on the long-range electrocardiogram scattergram, the target position is clicked through a mouse, the highlight display module automatically acquires the coordinates of the target position, and then all the areas are traversed to find the area containing the coordinates of the target position and light the area. The data processing module traverses all heart beats, acquires the heart beat of the area where the target position is located, and performs preset operation on the heart beat of the area where the target position is located, such as displaying an electrocardiogram, modifying the heart beat type, displaying a waveform overlay map and the like, so as to perform more detailed analysis on the area where the target position is located.
The invention also provides a processing method of the processing device for the long-range electrocardiogram scatter diagram, as shown in fig. 4, the method comprises the following steps:
s100, obtaining a target long-range electrocardiogram scatter diagram, and performing region division on the target long-range electrocardiogram scatter diagram according to a region division rule corresponding to the theme of the target long-range electrocardiogram scatter diagram;
s200, acquiring boundary points corresponding to the area according to the area attribute of the area and heartbeat detection data corresponding to the target long-range electrocardiogram scattergram;
s300, obtaining an area analysis result of the target long-range electrocardiogram scatter diagram according to the boundary points.
Because the existing long-range electrocardiogram scatter diagram has a large data volume, the boundaries between areas are not obvious, and the manual analysis difficulty and the working strength are high. In this embodiment, after the heart beat detection data is acquired by the electrocardiogram detection apparatus, the heart beat detection data is made into a scattergram, and a target long-range electrocardiogram scattergram to be processed is acquired. And then carrying out region division on the target long-range electrocardiogram scattergram according to a region division rule corresponding to the subject of the target long-range electrocardiogram scattergram, which is a problem of the target long-range electrocardiogram scattergram needing to be analyzed, so as to obtain a primary region division result of the target long-range electrocardiogram scattergram. And then acquiring boundary points corresponding to the regions according to the region attributes obtained after the preliminary region division and heart beat detection data corresponding to the target long-range electrocardiogram scattergram. Accurate region analysis results of the target long-range electrocardiogram scattergram with different themes can be obtained according to the obtained boundary points, so that the analysis difficulty and the working strength of the long-range electrocardiogram scattergram are reduced, and the analysis efficiency of medical personnel is improved.
In a specific embodiment, the step S100 further includes, before the step S:
s0, presetting the theme of the long-range electrocardiogram scattergram and the region division rule corresponding to the long-range electrocardiogram scattergram with different themes, and setting the region attribute corresponding to the region.
In specific implementation, different long-range electrocardiograph scattergram images focus on analyzing different problems, and the long-range electrocardiograph scattergram images with different problems have different region characteristics, in this embodiment, the theme of the long-range electrocardiograph scattergram image and the region division rule corresponding to the long-range electrocardiograph scattergram image with different themes are preset, and the region attribute corresponding to each region is set. In a specific embodiment, a plurality of themes are set in a square scattergram region, region division is performed on the square scattergram region of each theme, and a region attribute corresponding to each region is set, so that region division rules corresponding to long-range electrocardiogram scattergrams of different themes are obtained, and preliminary region division is performed on an obtained target long-range electrocardiogram scattergram in subsequent steps.
In a specific embodiment, the step S100 specifically includes:
s110, obtaining a target long-range electrocardiogram scatter diagram, and obtaining a theme of the target long-range electrocardiogram scatter diagram from a preset theme of the long-range electrocardiogram scatter diagram;
and S120, carrying out region division on the target long-range electrocardiogram scatter diagram according to a region division rule corresponding to the theme of the target long-range electrocardiogram scatter diagram.
In specific implementation, after the target long-range electrocardiogram scattergram is acquired, a theme can be selected for the target long-range electrocardiogram scattergram from preset themes of the long-range electrocardiogram scattergram according to a problem to be analyzed, and since the area division rules corresponding to the long-range electrocardiogram scattergram with different themes are preset, the area division corresponding to the theme can be performed on the target long-range electrocardiogram scattergram according to the selected different themes, so that a preliminary area analysis result of the long-range electrocardiogram scattergram can be quickly obtained.
In a specific embodiment, the step S200 specifically includes:
s210, when the shape feature of the area is an axis type, taking a coordinate point containing the largest quantity of heart beats in the area as a central point, starting to acquire coordinate points, corresponding to coordinate points on the axis on two sides of the central point, of heart beats not conforming to the heart beat type of the area from the central point as end points, and starting to acquire coordinate points, corresponding to coordinate points on two sides of the end points perpendicular to the axis direction, of heart beats not conforming to the heart beat type of the area from the end points as boundary points of the area;
s220, when the shape feature of the area is a circular type, sequentially encircling a circular area by using a coordinate point containing the largest number of heart beats in the area as a circular point and using an increasing radius, and when all heart beats conforming to the heart beat type of the area are contained in the circular area, using a boundary point of the circular area as a boundary point corresponding to the area;
and S230, when the shape feature of the area is a triangle type, a rectangle type or a polygon type, taking a coordinate point containing the largest quantity of heart beats in the area as a central point, and acquiring a coordinate point, corresponding to a coordinate point in the vertical direction of each side of the area, of which the heart beats do not conform to the heart beat type of the area from the central point as a boundary point corresponding to the area.
In specific implementation, when obtaining boundary points corresponding to the region according to the region attribute of the region and heartbeat detection data corresponding to the target long-range electrocardiograph scattergram, it is necessary to first determine whether the shape feature of the region is an axis type, a circular type, a triangular type, a rectangular type, or a polygonal type. When the shape feature of the area is an axis type, taking a coordinate point containing the largest heart beat number in the area as a central point, and judging whether heart beats corresponding to the coordinate points on the axes on two sides of the central point are in accordance with the heart beat type of the area or not from the central point; if so, continuously searching coordinate points, corresponding to the coordinate points, of the heart beat type which does not conform to the area on the axes on the two sides of the central point as end points. Then, whether the heart beats corresponding to the coordinate points on the two sides of the end point in the direction perpendicular to the axis conform to the heart beat type of the area or not is judged from the end point; if so, continuously searching coordinate points of the heartbeat type of the heartbeat non-conforming area corresponding to the coordinate points in the direction perpendicular to the axis at the two sides of the end point; if not, taking coordinate points of the heartbeat type of the areas, which are not met by the corresponding heartbeats on the two sides of the end points in the direction vertical to the axis, as boundary point coordinates corresponding to the areas.
In specific implementation, when the shape feature of the area is judged to be a circular type, a coordinate point containing the largest number of heart beats in the area is taken as a round point, a circular area is defined by increasing radiuses in sequence, and whether all heart beats conforming to the heart beat type of the area are contained in the circular area is judged; if not, a circular area is defined by increasing radius continuously until all heart beats which are in accordance with the heart beat type of the area are contained in the circular area.
In specific implementation, when the shape feature of the region is judged to be a triangle type, a rectangle type or a polygon type, a coordinate point containing the largest quantity of heart beats in the region is taken as a central point, and whether the heart beats corresponding to the coordinate points in the vertical direction of the sides of the region accord with the heart beat type of the region is judged from the central point; if yes, continuously searching a coordinate point which does not accord with the heart beat type of the area along the vertical direction of each side of the area; and if not, taking the coordinate point in the vertical direction of each side of the area as the boundary point corresponding to the area.
In a specific embodiment, after step S300, the method further includes:
s400, acquiring a region where a target position is located, and highlighting the region where the target position is located;
s500, acquiring the heart beat of the area where the target position is located, and performing preset operation on the heart beat of the area where the target position is located.
In a specific embodiment, when a user needs to analyze a certain position on the long-range electrocardiogram scattergram, the area where the target position is located can be automatically detected and highlighted by clicking the target position with a mouse. The highlighting of the region includes automatic search of a region boundary point set, region envelope rendering, region envelope highlighting, and the like. In specific implementation, when a user clicks a target position through a mouse, the coordinate of the target position is automatically acquired through triggering, then all the areas are traversed to find the area containing the coordinate of the target position and the area is lightened, the user can accurately acquire the area where any position on the long-range electrocardiogram scatter diagram is located and the area information of the area through clicking the mouse, and the analysis method is simple.
In a specific embodiment, after the region of the target position is acquired, the heart beat of the region of the target position can be further acquired by traversing all heart beats, calculating the coordinate of each heart beat, and recording all heart beats of which the heart beat coordinate falls in the region of the target position. After the heart beat of the area where the target position is located is acquired, preset operation can be performed on the heart beat of the area where the target position is located, for example, an electrocardiogram is displayed, the heart beat type is modified, a waveform overlay image is displayed, and therefore the area where the target position is located can be analyzed in a more detailed mode.
The invention also provides an electrocardiogram detection device, and the schematic block diagram can be shown in fig. 5. The device comprises a processor, a communication bus, a memory, a network interface, a display screen and a temperature sensor which are connected through a system bus. The memory stores a long-range electrocardiogram scatter diagram processing program which can be executed by the processor, and the communication bus realizes the connection communication between the processor and the memory. The memory comprises a nonvolatile storage medium and an internal memory, the memory stores a processing device provided with the long-range electrocardiogram scatter diagram, and the processor executes the long-range electrocardiogram scatter diagram processing program to realize a processing method of the long-range electrocardiogram scatter diagram. The network interface of the device is used for connecting and communicating with an external terminal through a network. The display screen of the device can be a liquid crystal display screen or an electronic ink display screen, and the temperature sensor of the device is arranged in the device in advance and used for detecting the current operating temperature of internal equipment.
It will be appreciated by those skilled in the art that the block diagram shown in fig. 5 is a block diagram of only a portion of the structure associated with the inventive arrangements and is not intended to limit the devices to which the inventive arrangements may be applied, and that a particular device may include more or less components than those shown, or may combine certain components, or have a different arrangement of components. In summary, the present invention discloses a processing apparatus, a processing method and a detection apparatus for a long-range electrocardiograph scattergram, wherein the processing apparatus comprises: the region division module is used for acquiring a target long-range electrocardio scattergram and carrying out region division on the target long-range electrocardio scattergram according to a region division rule corresponding to the theme of the target long-range electrocardio scattergram; a boundary acquisition module for acquiring boundary points corresponding to the region according to the region attribute of the region and the heart beat detection data corresponding to the target long-range electrocardiogram scattergram; and the analysis module is used for obtaining the region analysis result of the target long-range electrocardio scatter diagram according to the boundary points. According to the method, the theme of the long-range electrocardiogram scattergram and the corresponding region division rule thereof are preset, so that corresponding region division can be performed according to the selected theme when the target long-range electrocardiogram scattergram is analyzed, and the analysis difficulty and the working strength of medical staff are reduced; boundary points of the regions are obtained according to the region attributes and the heart beat detection data, and a final region analysis result is obtained according to the boundary points, so that the method can adapt to different long-range electrocardiogram detection data, and the analysis accuracy and definition of the long-range electrocardiogram scattergram output by the electrocardiogram detection device are improved.
It is to be understood that the invention is not limited to the examples described above, but that modifications and variations may be effected thereto by those of ordinary skill in the art in light of the foregoing description, and that all such modifications and variations are intended to be within the scope of the invention as defined by the appended claims.
Claims (10)
1. A device for processing a long range cardiac scattergram, the device comprising:
the region division module is used for acquiring a target long-range electrocardiogram scatter diagram and carrying out region division on the target long-range electrocardiogram scatter diagram according to a region division rule corresponding to the theme of the target long-range electrocardiogram scatter diagram;
the boundary acquisition module is used for acquiring boundary points corresponding to the region according to the region attribute of the region and the heartbeat detection data corresponding to the target long-range electrocardiogram scattergram;
and the analysis module is used for obtaining the region analysis result of the target long-range electrocardiogram scatter diagram according to the boundary points.
2. The apparatus for processing a long range cardiac scattergram of claim 1, further comprising:
the system comprises a presetting module and a processing module, wherein the presetting module is used for presetting the theme of the long-range electrocardio scatter diagram and the area division rule corresponding to the long-range electrocardio scatter diagram with different themes and setting the area attribute corresponding to the area.
3. The apparatus for processing a long range electrocardiographic scattergram according to claim 2, wherein the region dividing module specifically comprises:
the theme acquisition unit is used for acquiring a target long-range electrocardiogram scatter diagram and acquiring a theme of the target long-range electrocardiogram scatter diagram from a preset theme of the long-range electrocardiogram scatter diagram;
and the region dividing unit is used for performing region division on the target long-range electrocardio scatter diagram according to a region dividing rule corresponding to the theme of the target long-range electrocardio scatter diagram.
4. The apparatus for processing a long range electrocardiographic scattergram according to claim 2, wherein the region attribute includes a shape feature, a boundary feature, and a heart beat type; the shape features include an axis type, a circle type, a triangle type, a rectangle type, and a polygon type.
5. The apparatus for processing a long range electrocardiographic scattergram according to claim 4, wherein the boundary acquisition module specifically comprises:
a first boundary acquisition unit, configured to, when the shape feature of the region is an axis type, take a coordinate point in the region including the largest number of heartbeats as a center point, start acquiring, from the center point, coordinate points on the axis on both sides of the center point corresponding to heartbeats not conforming to the heart beat type of the region as an end point, and start acquiring, from the end point, coordinate points on both sides of the end point corresponding to coordinate points perpendicular to the axis direction corresponding to heart beats not conforming to the heart beat type of the region as boundary points of the region;
a second boundary acquisition unit, configured to, when the shape feature of the region is a circular type, sequentially circle a circular region with increasing radii by using a coordinate point, as a dot, in the region that includes the largest number of heartbeats, and when all heartbeats that conform to the heart beat type of the region are included in the circular region, take a boundary point of the circular region as a boundary point corresponding to the region;
and a third boundary acquiring unit, configured to, when the shape feature of the region is a triangle type, a rectangle type, or a polygon type, take a coordinate point in the region that includes the largest number of heart beats as a center point, and acquire, from the center point, a coordinate point corresponding to a coordinate point in a vertical direction of each side of the region, where a heart beat does not conform to the heart beat type of the region, as a boundary point corresponding to the region.
6. The apparatus for processing a long range cardiac scattergram of claim 1, further comprising:
the highlight display module is used for acquiring a region where a target position is located and highlighting the region where the target position is located;
and the data processing module is used for acquiring the heart beat of the area where the target position is located and performing preset operation on the heart beat of the area where the target position is located.
7. A method for processing a long range cardiac scattergram by the apparatus for processing a long range cardiac scattergram according to claim 1, comprising the steps of:
acquiring a target long-range electrocardiogram scattergram, and performing region division on the target long-range electrocardiogram scattergram according to a region division rule corresponding to the theme of the target long-range electrocardiogram scattergram;
acquiring boundary points corresponding to the region according to the region attribute of the region and heartbeat detection data corresponding to the target long-range electrocardiogram scattergram;
and obtaining the region analysis result of the target long-range electrocardiogram scatter diagram according to the boundary points.
8. The method for processing the long range electrocardiographic scattergram according to claim 7, wherein the step of obtaining the target long range electrocardiographic scattergram and performing region division on the target long range electrocardiographic scattergram according to the region division rule corresponding to the subject of the target long range electrocardiographic scattergram specifically comprises:
the method comprises the steps of presetting a theme of a long-range electrocardiogram scatter diagram and an area division rule corresponding to the long-range electrocardiogram scatter diagram with different themes, and setting an area attribute corresponding to the area.
9. The method for processing a long range electrocardiographic scattergram according to claim 7, wherein the step of obtaining a target long range electrocardiographic scattergram and performing region division on the target long range electrocardiographic scattergram according to a region division rule corresponding to a subject of the target long range electrocardiographic scattergram further comprises:
acquiring a target long-range electrocardiogram scatter diagram, and acquiring the theme of the target long-range electrocardiogram scatter diagram from the preset theme of the long-range electrocardiogram scatter diagram;
carrying out region division on the target long-range electrocardio scattergram according to a region division rule corresponding to the theme of the target long-range electrocardio scattergram;
the region attributes include shape features, boundary features, and heart beat type; the shape features include an axis type, a circle type, a triangle type, a rectangle type, and a polygon type;
the step of acquiring boundary points corresponding to the region according to the region attribute of the region and the heart beat detection data corresponding to the target long-range electrocardiogram scattergram specifically includes:
when the shape feature of the area is an axis type, taking a coordinate point containing the largest heart beat number in the area as a central point, acquiring coordinate points, corresponding to the coordinate points on the axis on two sides of the central point, of heart beats not conforming to the heart beat type of the area from the central point as end points, and acquiring coordinate points, corresponding to the coordinate points on two sides of the end points perpendicular to the axis direction, of heart beats not conforming to the heart beat type of the area from the end points as boundary points of the area;
when the shape feature of the area is a circular type, a coordinate point containing the largest number of heart beats in the area is taken as a circular point, a circular area is defined by increasing radiuses in sequence, and when all heart beats conforming to the heart beat type of the area are contained in the circular area, the boundary point of the circular area is taken as the boundary point corresponding to the area;
when the shape feature of the area is a triangle type, a rectangle type or a polygon type, taking a coordinate point containing the largest number of heart beats in the area as a central point, and acquiring a coordinate point, corresponding to a coordinate point in the vertical direction of each side of the area, of which the heart beats do not conform to the heart beat type of the area from the central point as a boundary point corresponding to the area.
10. An electrocardiogram detection device is characterized by comprising a processor, a communication bus and a memory;
the memory is stored with a long-range electrocardio scattergram processing program which can be executed by the processor;
the communication bus realizes connection communication between the processor and the memory;
the memory stores processing means provided with a long range cardiac scattergram according to any one of claims 1 to 6, and the processor implements the processing method steps of the long range cardiac scattergram according to any one of claims 7 to 9 when executing the long range cardiac scattergram processing program.
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