CN116327114A - Method for reviewing monitor, monitor and computer readable storage medium - Google Patents

Abstract

The application relates to the technical field of monitors, and discloses a review method of a monitor, the monitor and a computer readable storage medium. The method comprises the following steps: displaying a monitoring interface, wherein the monitoring interface is used for displaying historical physiological data of a monitored person; and responding to a viewing instruction aiming at the alarm event mark on the monitoring interface, and jumping to a data analysis interface corresponding to the alarm event mark, wherein the alarm event mark is obtained by marking abnormal data in the historical physiological data. Through the mode, the operation flow of the user during abnormal review can be reduced, the efficiency of checking abnormal data is improved, and the user experience is improved.

Description

Method for reviewing monitor, monitor and computer readable storage medium

Technical Field

The present application relates to the technical field of monitors, and in particular, to a method for reviewing a monitor, and a computer readable storage medium.

Background

The monitor is an important instrument for monitoring physiological data of a patient, and can display numerical values of a plurality of physiological data and curves or waveforms of certain physiological data, wherein the physiological parameters are important basis for emergency treatment and treatment of doctors. Especially in the case of patient critical, the monitor needs to continuously monitor various physiological parameters of the patient for a long time, display the change trend and give an alarm prompt of critical conditions.

The checking of alarm events in the related art is complicated, and the working efficiency of medical staff is reduced.

Disclosure of Invention

The technical problem that this application mainly solves is to provide the review method of monitor, monitor and computer readable storage medium, can reduce the operation flow when the user carries out unusual review, improves the efficiency of looking over unusual data, improves user experience.

In order to solve the above problems, a technical solution adopted in the present application is to provide a method for reviewing a monitor, which includes: displaying a monitoring interface, wherein the monitoring interface is used for displaying historical physiological data of a monitored person; and responding to a viewing instruction aiming at the alarm event mark on the monitoring interface, and jumping to a data analysis interface corresponding to the alarm event mark, wherein the alarm event mark is obtained by marking abnormal data in the historical physiological data.

The data analysis interface is provided with a data display area which is used for displaying all physiological data acquired simultaneously with the abnormal data; the method further comprises the steps of: and responding to a viewing instruction for the data display area, and jumping to a monitoring interface.

The monitoring interface is a trend review interface, and the data analysis interface is an alarm event detail interface; displaying a monitoring interface, comprising: displaying a trend review interface; responding to a viewing instruction for the alarm event markers on the monitoring interface, jumping to a data analysis interface corresponding to the alarm event markers, and comprising: responding to a checking instruction aiming at the alarm event mark, and jumping to an alarm event detail interface corresponding to the alarm event mark; in response to a view instruction for the data display area, jumping to a monitoring interface, comprising: in response to a view instruction for the data display area, a jump is made to a trend review interface.

The trend review interface comprises a physiological data trend display area and a physiological data numerical value display area; the physiological data trend display area is used for displaying at least one trend chart of physiological data, and the physiological data value display area is used for displaying physiological data values at appointed moments in the trend chart; the method further comprises the steps of: in response to a sliding operation for the physiological data value display area, switching the physiological data displayed by the physiological data value display area, and switching the trend graph in the physiological data trend display area so that the trend graph corresponds to the physiological data displayed by the physiological data value display area.

Wherein the method further comprises: responding to an alarm preview instruction on a trend review interface, and displaying all alarm events corresponding to the monitored person; responding to a checking instruction aiming at a target alarm event in all alarm events, and jumping to an alarm event detail interface corresponding to the target alarm event; the alarm event detail interface is used for displaying all physiological data acquired simultaneously with the abnormal data, alarm types corresponding to the abnormal data and/or waveforms corresponding to the abnormal data.

The monitoring interface displays waveforms corresponding to the historical physiological data; the alarm event markers are located at abnormal wavebands in the waveform; responding to a viewing instruction for the alarm event mark on the monitoring interface, and before jumping to a data analysis interface corresponding to the alarm event mark, comprising: responding to an alarm preview instruction aiming at an alarm event mark, and displaying a sub display interface; and displaying related information corresponding to the alarm event mark on the sub-display interface, wherein the related information comprises alarm grade, physiological data, event generation time and statistical information of the same type of alarm.

The data analysis interface is provided with a waveform display area which is used for displaying a wave band corresponding to the abnormal data; the method further comprises the steps of: and responding to a viewing instruction for the waveform display area, and jumping to a monitoring interface.

The monitoring interface is a holographic waveform interface, and the data analysis interface is an alarm event detail interface; displaying a monitoring interface, comprising: displaying a holographic waveform interface; responding to a viewing instruction for the alarm event markers on the monitoring interface, jumping to a data analysis interface corresponding to the alarm event markers, and comprising: responding to a checking instruction aiming at the alarm event mark, and jumping to an alarm event detail interface corresponding to the alarm event mark; in response to a view instruction for the waveform display area, jumping to a monitoring interface, comprising: in response to a view instruction for the waveform display area, a jump is made to the holographic waveform interface.

The same physiological data displayed by the monitoring interface and the data analysis interface are stored in the same storage space.

In order to solve the above problem, another technical solution adopted in the present application is to provide a monitor, where the monitor includes a processor, and a memory and a display screen coupled to the processor, and the memory stores a computer program, and the processor is configured to execute the computer program to implement a method provided in the above technical solution.

In order to solve the above problem, another technical solution adopted in the present application is to provide a computer readable storage medium, where a computer program is stored, and the computer program when executed by a processor implements the method provided in the above technical solution.

The beneficial effects of this application are: unlike the prior art, the method for reviewing the monitor provided in the present application includes: displaying a monitoring interface, wherein the monitoring interface is used for displaying historical physiological data of a monitored person; and responding to a viewing instruction aiming at the alarm event mark on the monitoring interface, and jumping to a data analysis interface corresponding to the alarm event mark, wherein the alarm event mark is obtained by marking abnormal data in the historical physiological data. Through the mode, the alarm event mark is associated with the data analysis interface, so that a user can directly operate the alarm event mark to jump to the data analysis interface corresponding to the abnormal data, the operation flow of the user during abnormal review is reduced, the viewing efficiency of the abnormal data is improved, and the user experience is improved.

Drawings

FIG. 1 is a flow chart of a first embodiment of a method for reviewing a monitor provided herein;

FIG. 2 is a flow chart of a second embodiment of a review method of the monitor provided in the present application;

FIG. 3 is a flow chart of a third embodiment of a review method of a monitor provided herein;

FIG. 4 is a flow chart of a fourth embodiment of a review method of a monitor provided herein;

FIG. 5 is a flowchart of a fifth embodiment of a review method of a monitor provided herein;

FIG. 6 is a flowchart of a sixth embodiment of a review method of a monitor provided herein;

FIG. 7 is a schematic diagram of a graphical user interface of a trend review function provided herein;

FIG. 8 is a schematic diagram of a graphical user interface of another trend review function provided herein;

FIG. 9 is a schematic diagram of a graphical user interface of another alert review list provided herein;

FIG. 10 is a flow diagram of one embodiment of an alert review interface provided herein;

FIG. 11 is a schematic diagram of an embodiment of a monitor provided herein;

fig. 12 is a schematic structural diagram of an embodiment of a computer-readable storage medium provided in the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is to be understood that the specific embodiments described herein are for purposes of illustration only and are not limiting. It should be further noted that, for convenience of description, only some, but not all of the structures related to the present application are shown in the drawings. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the present disclosure, are within the scope of the present disclosure.

The terms "first," "second," and the like in this application are used for distinguishing between different objects and not for describing a particular sequential order. Furthermore, the terms "comprise" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those listed steps or elements but may include other steps or elements not listed or inherent to such process, method, article, or apparatus.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment may be included in at least one embodiment of the present application. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those of skill in the art will explicitly and implicitly appreciate that the embodiments described herein may be combined with other embodiments.

Referring to fig. 1, fig. 1 is a flowchart of a first embodiment of a method for reviewing a monitor provided in the present application. The method comprises the following steps:

Step 11: displaying a monitoring interface; the monitoring interface is used for displaying historical physiological data of the monitored person.

In the monitor, different monitoring interfaces have different functions. For example, the main operation interface is used for displaying main monitoring data such as electrocardiograph data, pulse data and blood oxygen data, and is also used for providing access to the rest operation interfaces. The other operation interfaces have corresponding functions, such as a review function, and the monitoring interface in the embodiment of the application is a review interface for correspondingly reviewing various historical physiological data, where the historical physiological data can be displayed in different expression forms, such as waveforms and trend graphs, and forms such as a trend review interface, a holographic waveform interface, an alarm review interface, a trend table review interface, a blood pressure review interface, a 12-lead analysis review interface, and a respiratory oxygenation review interface.

Thus, in some embodiments, a function key corresponding to each interface may be provided on each operation interface to switch the display interface to the corresponding function interface when the function key is selected. The function keys may be virtual keys, i.e. displayed on the monitoring interface. The selection mode can be manual touch control or mouse click, or automatic selection of the monitor operating system.

In other embodiments, the function key may be a physical key, and is disposed on an operation panel of the monitor, and when the user needs to view the corresponding interface, the corresponding function key is selected, and the display interface is switched to the corresponding function interface.

Step 12: and responding to a viewing instruction aiming at the alarm event mark on the monitoring interface, and jumping to a data analysis interface corresponding to the alarm event mark, wherein the alarm event mark is obtained by marking abnormal data in the historical physiological data.

When any one of the physiological data of the monitored person at any moment exceeds the corresponding threshold value, determining that the physiological data is abnormal, and marking the abnormal data as an alarm event.

For example, when physiological data is obtained through real-time monitoring, whether the physiological data is abnormal or not can be judged, if yes, alarm event marking is carried out on the data at the moment, and therefore follow-up event review is facilitated.

For another example, the alarm event markers may be correspondingly displayed at corresponding times while viewing the historical physiological data of the subject.

At this time, when the alarm event mark is checked, for example, clicking the alarm event mark on the monitoring interface, for example, long-press operation and double-click operation, the interface jump is directly performed, and the jump is performed to the data analysis interface corresponding to the alarm event mark.

All the collected physiological data corresponding to the moment of the abnormal data and the alarm type corresponding to the alarm event can be displayed on the data analysis interface. Such as an alarm type with too high heart rate, too high pulse, too low heart rate, etc.

In this embodiment, the monitoring interface is used to display the historical physiological data of the monitored person by displaying the monitoring interface; responding to a checking instruction aiming at the alarm event mark on the monitoring interface, and jumping to a data analysis interface corresponding to the alarm event mark, and associating the alarm event mark with the data analysis interface, so that a user can directly operate the alarm event mark to jump to the data analysis interface corresponding to the abnormal data, the operation flow of the user during abnormal review is reduced, the checking efficiency of the abnormal data is improved, and the user experience is improved.

Referring to fig. 2, fig. 2 is a flowchart of a second embodiment of a review method of a monitor provided in the present application. The method comprises the following steps:

step 21: displaying a monitoring interface; the monitoring interface is used for displaying historical physiological data of the monitored person.

Step 22: and responding to a viewing instruction aiming at the alarm event mark on the monitoring interface, and jumping to a data analysis interface corresponding to the alarm event mark, wherein the alarm event mark is obtained by marking abnormal data in the historical physiological data.

Steps 21 to 22 have the same or similar technical solutions as the above embodiments, and are not described here again.

Step 23: and responding to a viewing instruction of a data display area of the data analysis interface, and jumping to the monitoring interface.

The data analysis interface is provided with a data display area which is used for displaying all physiological data acquired simultaneously with the abnormal data.

At this time, when the data display area is checked, for example, any area of the data display area is clicked, for example, long press operation and double click operation are performed, the interface jump is directly performed, and the previous monitoring interface is jumped.

In this embodiment, the alarm event mark is associated with the data analysis interface, so that a user can directly operate the alarm event mark to jump to the data analysis interface corresponding to the abnormal data, and the operation of the data analysis interface directly jumps to the monitoring interface, so that the operation flow of the user during abnormal review can be reduced, the viewing efficiency of the abnormal data is improved, and the user experience is improved.

Referring to fig. 3, fig. 3 is a flowchart of a third embodiment of a review method of a monitor provided in the present application. The method comprises the following steps:

step 31: a trend review interface is displayed.

In this embodiment, the monitoring interface is a trend review interface, which is used to display historical physiological data of the monitored person. Such as HR (Heart Rate), SPO2 (blood oxygen saturation), PR (Pulse Rate). Multiple physiological data can be displayed simultaneously at the trend review interface.

Step 32: and responding to a viewing instruction for the alarm event mark, and jumping to an alarm event detail interface corresponding to the alarm event mark.

The alarm event markers on the trend review interface are generated when physiological data is obtained by real-time monitoring and the physiological data is abnormal data.

A time selection may be made at the trend review interface to display a historical physiological data trend graph of the monitored person for a corresponding period of time on the trend review interface. If an alarm event exists in the period of time, the alarm event is marked at the corresponding moment so that the alarm event mark can be checked with subsequent review. In particular, the alarm event markers may be differentiated according to different levels. For example, the grade is divided into a primary, a secondary and a tertiary. Wherein, the importance degree of the third stage is larger than that of the second stage and the first stage, and the importance of the second stage is higher than that of the first stage. The alarm event markers are displayed with different colors, such as the color of the alarm event marker corresponding to the third level is set to red, the color of the alarm event marker corresponding to the second level is set to orange, and the color of the alarm event marker corresponding to the first level is set to yellow.

Abnormal data of the alarm and other physiological data collected at the same time can be displayed on the alarm event detail interface. And additionally displaying the abnormal data. For example, abnormal data is displayed in red. And displaying waveform data corresponding to the abnormal data on an alarm event detail interface. Specifically, the range of the waveform data is a range of a preset time length. For example, based on the first time of the abnormal data, the waveform data may range from N times before the first time to M times after the first time, where M and N are natural numbers greater than zero.

Step 33: and responding to a viewing instruction of a data display area of the alarm event detail interface, and jumping to a trend review interface.

The alarm event detail interface is provided with a data display area which is used for displaying all physiological data acquired simultaneously with the abnormal data.

At this time, when the data display area is checked, for example, any area of the data display area is clicked, for example, long press operation and double click operation are performed, interface skip is directly performed, and the previous trend review interface is skipped.

In the embodiment, the alarm event mark on the trend review interface is associated with the alarm event detail interface, so that a user can directly operate the alarm event mark to jump to the alarm event detail interface and directly jump to the trend review interface, the operation flow of the user during abnormal review can be reduced, the viewing efficiency of abnormal data is improved, and the user experience is improved.

In some embodiments, the trend review interface includes a physiological data trend display area and a physiological data value display area; the physiological data trend display area is used for displaying at least one trend chart of physiological data, and the physiological data value display area is used for displaying physiological data values at appointed moments in the trend chart.

The user may slide the physiological data display area at the trend review interface to view more physiological data. Wherein, in response to the sliding operation for the physiological data value display area, the physiological data displayed in the physiological data value display area is switched, and the trend graph in the physiological data trend display area is switched so that the trend graph corresponds to the physiological data displayed in the physiological data value display area.

In this way, the user can conveniently switch and view more physiological data, and when the other physiological data also have corresponding alarm event marks, the user jumps to the alarm event detail interface by viewing the alarm event marks according to the mode of any embodiment.

Referring to fig. 4, fig. 4 is a flowchart of a fourth embodiment of a review method of a monitor provided in the present application. The method comprises the following steps:

step 41: and responding to an alarm preview instruction on the trend review interface, and displaying all alarm events corresponding to the monitored person.

In some embodiments, the trend review interface may be at least one of a trend graph review interface, a trend table review interface, a blood pressure review interface, an alarm review interface, a holographic waveform review interface, a 12-lead analysis review interface, and a respiratory oxygenation review interface.

And setting an alarm preview instruction on the trend review interface, and displaying an alarm event overview interface in response to the alarm preview instruction on the trend review interface, wherein all alarm events corresponding to the monitored person are displayed in the alarm event overview interface.

The content of the alarm event shown here is thumbnail information. The thumbnail information refers to part of information of the alarm event, wherein the thumbnail information contains the generation time of the alarm event.

The description is given with reference to fig. 7 and 9:

fig. 7 is a trend graph review interface. In fig. 7, there is an alarm preview control 106. Upon selection of the alert preview control 106, in response to reviewing the alert preview instructions on the interface for the trend graph, all alert events corresponding to the monitored person are displayed, specifically, the interface shown in fig. 7 is switched to the interface shown in fig. 9. In the interface shown in fig. 9, all alarm events corresponding to the monitored person are displayed. Such as too low heart rate, too low SPO2, too high T1, choking alarms, and corresponding waveform recordings.

The description is given with reference to fig. 8 and 9:

fig. 8 is a holographic waveform review interface. In fig. 8, there is an alarm preview control 207. Upon selection of the alert preview control 207, all alert events corresponding to the monitored person are displayed in response to reviewing the alert preview instructions on the interface for the holographic waveform, specifically, the interface shown in fig. 8 is switched to the interface shown in fig. 9. In the interface shown in fig. 9, all alarm events corresponding to the monitored person are displayed. Such as too low heart rate, too low SPO2, too high T1, choking alarms, and corresponding waveform recordings.

Step 42: and responding to a viewing instruction for a target alarm event in all alarm events, and jumping to an alarm event detail interface corresponding to the target alarm event.

The alarm event detail interface is used for displaying all physiological data acquired simultaneously with the abnormal data, alarm types corresponding to the abnormal data and/or waveforms corresponding to the abnormal data.

The description is given with reference to fig. 9 and 10:

in the interface shown in fig. 9, all alarm events corresponding to the monitored person are displayed. When any alarm event in fig. 9 is selected, the interface shown in fig. 9 is jumped to the display interface shown in fig. 10. FIG. 10 is an alarm event detail interface. The alarm event details interface shown in fig. 10 is a detailed presentation for an alarm event with a heart rate that is too high. The alarm time, heart rate waveform, remaining physiological data, etc. are shown in fig. 10. In fig. 10, a return alarm list control 403 is provided, and when the alarm list control 403 is selected, the interface shown in fig. 10 is jumped to the interface shown in fig. 9.

And then, if the data display area of the alarm event detail interface is checked, the monitor responds to a check instruction aiming at the data display area of the alarm event detail interface and jumps to a trend review interface.

Referring to fig. 5, fig. 5 is a flowchart of a fifth embodiment of a review method of a monitor provided in the present application. The method comprises the following steps:

step 51: displaying a monitoring interface; the monitoring interface is used for displaying historical physiological data of the monitored person.

In some embodiments, the monitoring interface displays waveforms corresponding to historical physiological data; the alarm event markers are located at abnormal bands in the waveform so that the user is intuitively aware of the abnormal physiological data at the time the alarm event occurs.

Step 52: and responding to an alarm preview instruction aiming at the alarm event mark, and displaying a sub-display interface.

In some embodiments, the alert preview instruction may be generated by operating on an alert event flag. For example, the operation on the monitoring interface is performed by a mouse, and when the cursor of the mouse is placed on the alarm event mark, an alarm preview instruction is generated. And further, responding to an alarm preview instruction aiming at the alarm event mark, and displaying a sub-display interface. For another example, the operation on the monitoring interface is performed by touch, and then an alarm preview instruction is generated when the alarm event mark is detected to be touched for the first time. And further, responding to an alarm preview instruction aiming at the alarm event mark, and displaying a sub-display interface. In other embodiments, whether to generate the alarm preview instruction may be determined according to the touch time. If the touch time is a first time length, and the first time length is smaller than a preset time length, an alarm preview instruction is generated.

And displaying related information corresponding to the alarm event mark on the sub-display interface, wherein the related information comprises alarm grade, physiological data, event generation time and statistical information of the same type of alarm.

Through the display of the sub-display interface, the user can then quickly learn the basic information of the alarm event, so as to determine whether to perform interface jump.

Step 53: and responding to a viewing instruction aiming at the sub-display interface, and jumping to a data analysis interface corresponding to the alarm event mark.

In some embodiments, the data analysis interface is provided with a waveform display area for displaying waveforms corresponding to the abnormal data; and responding to a viewing instruction for the waveform display area, and jumping to a monitoring interface.

In other embodiments, a jump may be made to a data analysis interface corresponding to an alarm event marker in response to a view instruction for the alarm event marker.

In this embodiment, relevant information of the alarm event is displayed through the sub-display interface, so that a user decides whether to jump to the data analysis interface, the sub-display interface is associated with the alarm event detail interface, so that the user can jump to the data analysis interface by directly displaying the sub-display interface, and the operation of the data analysis interface can jump to the monitoring interface directly, thereby reducing the operation flow when the user performs abnormal review, improving the viewing efficiency of abnormal data, and improving the user experience.

Referring to fig. 6, fig. 6 is a flowchart of a sixth embodiment of a review method of a monitor provided in the present application. The method comprises the following steps:

step 61: displaying a holographic waveform interface.

The holographic waveform interface is used for displaying waveform data of physiological data of the monitored person. Such as electrocardiographic data, end-tidal carbon dioxide data, volume pulse rate, and pulse intensity.

Step 62: and responding to a viewing instruction for the alarm event mark, and jumping to an alarm event detail interface corresponding to the alarm event mark.

Abnormal data of the alarm and other physiological data collected at the same time can be displayed on the alarm event detail interface. And additionally displaying the abnormal data. For example, abnormal data is displayed in red. And displaying waveform data corresponding to the abnormal data on an alarm event detail interface. Specifically, the range of the waveform data is a range of a preset time length. For example, based on the first time of the abnormal data, the waveform data may range from N times before the first time to M times after the first time, where M and N are natural numbers greater than zero.

Step 63: in response to a view instruction for the waveform display area, a jump is made to the holographic waveform interface.

The alarm event detail interface is provided with a waveform display area, and the data display area is used for displaying waveform data corresponding to the abnormal data.

At this time, when the waveform display area is checked, for example, any area of the waveform display area is clicked, for example, long press operation and double click operation are performed, the interface jump is directly performed, and the previous holographic waveform interface is jumped.

In this embodiment, the alarm event mark on the holographic waveform interface is associated with the alarm event detail interface, so that a user can directly operate the alarm event mark to jump to the alarm event detail interface, and the operation of the alarm event detail interface jumps directly to the holographic waveform interface, so that the operation flow of the user during abnormal review can be reduced, the viewing efficiency of abnormal data can be improved, and the user experience can be improved.

The description is given with reference to fig. 8 and 10:

fig. 8 is a holographic waveform review interface. In fig. 8, there is a waveform review area 201. Waveforms of the corresponding historical physiological data are displayed in the waveform review area 201. And an alarm event flag 205 corresponding to an abnormal band.

Upon selection of the alarm event tab 205, an interface switch will be made in response to a view instruction for the alarm event tab 205. Specifically, the interface shown in fig. 8 is switched to the interface shown in fig. 10. It will be appreciated that fig. 8 and 10 are merely exemplary illustrations. Specifically, when the alarm event markers 205 in fig. 8 are viewed, waveforms of abnormal historical physiological data corresponding to the alarm event markers, and all physiological data at the time of the history are shown in fig. 10 after the jump.

In a certain scenario, the inventor researches for a long time to find that the monitors in the related art store data with different functions respectively, so that the burden of storing the monitors is increased. That is, if the physiological data displayed by different functional interfaces are the same physiological data generated at the same time, only one part of data is stored in the memory, so that all the functional interfaces share the physiological data, and the pressure of the data storage of the monitor is reduced.

In an application scenario, the following description is made with reference to fig. 7 to 10:

referring to fig. 7, fig. 7 is a graphical user interface of a trend review function provided herein, which corresponds to a trend graph review interface. The trend graph review interface includes: review content information field 101, first alarm event flag 102, first physiological parameter area 103, parameter trend waveform 104, trend group settings item 105, alarm preview function entry 106, event flag switch 107, data refresh key 108, trend review settings 109, window time 110, first cursor 111, cursor time 112, regular event flag 113, and first review progress bar 114.

The review content information bar 101 is used to provide access to other review functions, as shown in fig. 7, corresponding trend graph control, trend table control, blood pressure review control, alarm review control, holographic waveform review control, 12-lead analysis review control, and respiratory oxygenation review control in the review content information bar 101. When any control is selected in the review content information field 101, the display content on the right side of the review content information field 101 is switched.

The first alarm event indicia 102 is used to provide visual alarm indications in a trend review area. Specifically, the first alarm event flag 102 is set at the corresponding abnormal band.

The first physiological parameter area 103 is used for reviewing parameter values at a specified time; the parameter trend waveform 104 is used for connecting the physiological parameter values in the window time period into a waveform, so that a user can observe the parameter change trend conveniently.

The trend group setting item 105 is used to group physiological parameters having similar physiological meanings into trend groups, so that the user can conveniently and intensively view the physiological parameters.

The alarm preview function portal 106 is configured to provide a full-time alarm event preview function that facilitates user location of specified alarm events.

The event flag switch 107 is a regular event flag 113 display switch, and when the event flag switch 107 is in an on state, a regular event flag 113 is displayed in the corresponding parameter trend waveform 104 when a regular event is generated, and when the event flag switch 107 is in an off state, a regular event flag 113 is not displayed when a regular event is generated.

The data refresh button 108 quickly refreshes the data of the interface.

The trend review settings 109 are used to support user-defined review parameters.

The window time 110 is used to adjust the resolution of the trend graph, e.g., set the window time to 6 minutes, 7 minutes, 5 minutes, etc.; the first cursor 111 is used for supporting movement to view the physiological parameter value at the positioning moment; cursor time 112, which is used to indicate the current cursor positioning time; event markers 113, providing visual event marker indications in the trend review area, such as eating, washing, etc.; the first review progress bar 114 is used to view the current review progress.

In the application scenario, at most 3 physiological parameter trend curves are displayed on the same screen on a single page in the first physiological parameter area 103, so that a user is supported to view more review parameters through page up and down actions in the area of the first physiological parameter area 103, and is supported to slide left and right in the parameter trend waveform 104 to view parameter trends at different moments, and the first review progress bar 114 displays the current review progress. The trend graph window time 110 is selected by the user, and the data sampling point of the trend graph is determined by the set window duration. The longer the window time, the lower the data resolution and vice versa.

The alarm event and the trend window establish time correlation, the first alarm event mark 102 is displayed on the parameter trend waveform 104 corresponding to the alarm time, and the color of the first alarm event mark 102 is displayed according to the alarm grade. The alarm time is accurate to seconds and the first alarm event indicia 102 is displayed positioned at the point in time closest to the time of alarm occurrence according to the current window time resolution. The system receives an instruction of clicking the first alarm event mark 102, a page pops up a tag popup window for recording alarm event content, the first cursor 111 is automatically positioned to the alarm event occurrence time, the cursor time 112 displays the positioning time of the current cursor, the first physiological parameter area 103 displays a physiological parameter value at the cursor positioning time, and the physiological parameter value related to alarm displays a font color consistent with the alarm level. The alarm preview 106 looks at the full period of patient data, the patient monitors all alarm events from the start time to the time of entering the trend review page, receives instructions to look at an alarm event, and the trend window center time and review first cursor 111 quickly locates to the alarm occurrence time. The data refresh key 108 quickly refreshes the latest time parameter data, updating the trend content. After turning on the event marker switch 107, the parameter trend waveform 104 displays a regular event marker 113, and the regular event marker 113 is displayed to support clicking preview of manual events such as medical operations and daily life self-care items such as injection, medication, eating, rehabilitation exercise. The trend review setting 109, entering a review parameter review page, supports the user to customize and review the physiological parameters to be reviewed, and review the successful refresh parameter trend waveform 104 and the first physiological parameter area 103.

Referring to fig. 8, fig. 8 is a schematic diagram of a graphical user interface of another trend review function provided herein. When the holographic waveform control is selected, the holographic waveform interface is displayed on the right side of the review content information bar. The abnormal parameter waveform is one of the manifestations of vital sign change, the holographic waveform review function records the parameter waveform of the monitoring full period in equal proportion, stores waveform data points according to waveform sampling frequency, and redraws the historical waveform at the holographic waveform interface. The holographic waveform can facilitate medical staff to more intuitively check patient data.

The holographic waveform interface comprises: a waveform review section 201, a second review progress bar 202, a review progress adjustment block 203, a second cursor 204, a second alarm event flag 205, a window time setting 206, an alarm preview entry 207, and a waveform review setting 208.

Wherein the waveform review area 201 is for displaying the stored compressed waveform; the second review progress bar 202 is used to view the current waveform review progress; the review progress adjusting block 203 is configured to adjust a review progress of the current review window, and the second cursor 204 is configured to support moving a physiological parameter value at a view positioning time; the second alarm event indicia 205 is used to provide visual alarm indications in the waveform review area and the window time setting 206 is used to adjust the window display resolution; the alarm preview entrance 207 is used for providing a full-time alarm event preview function, so that a user can conveniently locate and designate an alarm event; the waveform review settings 208 are used to support user-defined selection of the parameter waveforms that need to be reviewed.

The waveform review section 201 supports simultaneous review of up to 3 parameter waveforms, entering the waveform selection page through the waveform review settings 208, and hooking the parameter waveforms that need to be reviewed. The review progress adjustment block 203 displays the current review progress in real-time, supporting dragging the review progress adjustment block 203 within the scope of the second review progress bar 202 to select a review interval, allowing the user to customize the slider time span. The user adjusts the current window duration through window time setting 206, supporting the gesture to flip back and forth to view waveform changes for more time. The alarm event establishes a time correlation with the waveform review window, and a second alarm event marker 205 is displayed in the waveform review area 201, positioned on the parameter waveform generating the alarm, and the marker color is displayed according to the alarm level, and the parameter waveform in the period from the start to the end of the alarm has a distinguishing display, including but not limited to waveform thickening, waveform color change and waveform background color filling. The system receives an instruction of clicking the second alarm event mark 205, the page pops up a label popup window for recording the alarm event content, the second cursor 204 positions the occurrence time of the alarm event, and the physiological parameter value of the current positioning time is displayed on the cursor. The alarm preview portal 207 views the alarm event from the patient monitoring start time to the time of entering the holographic waveform review page for the full period of patient data, receives instructions to view an alarm event, and the window center time and second cursor 204 are quickly positioned to the alarm occurrence time.

Referring to fig. 9, fig. 9 is a schematic diagram of a graphical user interface of another alert review list provided herein. When the alarm review control is selected, the right side of the review content information bar is displayed as an alarm event review page. Wherein the alarm event review page is displayed as a list entry, the interface comprising: an alarm event content display area 301, an alarm waveform display area 302, an arrangement adjustment control 303, and an alarm list setting control 304.

Wherein, the alarm event content display area 301 presents all alarm events meeting the current screening condition in a list form, so that the medical staff can check the physiological abnormal condition of the patient in a concentrated way. The alarm waveform display area 302 is used for loading the compressed waveform of the alarm event record, so that the user can preview the waveform quickly. The arrangement adjustment control 303 is used for providing various arrangement rules, and the user adjusts the list display order according to the use habit; the alarm list setting control 304 is used to support user-defined screening of alarm events that need review. Arrangement adjustment control 303 is used to adjust the order of alarm event entries in the alarm list. The sorting rule may be arranged in ascending or descending order according to the alarm level, or arranged in ascending or descending order according to the alarm event; or ordered in numerical or alphabetical order/reverse order. The alarm event content display area 301 is configured to display alarm basic information, where the alarm basic information includes: the alarm level, the alarm starting time and the alarm content, wherein the alarm level can be displayed in a text, color or symbol mode. The alarm waveform display area 302 includes: the alarm triggering condition and the alarm parameter compress waveform. Wherein, part of physiological parameters have no waveform record, such as body temperature, blood pressure and the like. Thus, the waveform display area 302 has a case where an alarm trigger condition alone occurs. The alarm event setting control 304 enters an alarm event screening page, and screening items include, but are not limited to, parameter names, alarm grades, alarm types, such as physiological alarms, technical alarms, life alarms, alarm time periods, successful checkups and refreshing alarm lists. Clicking any item in the alarm event content display area 301 and the alarm waveform display area 302, and entering an alarm event detail interface. And when the number of the alarm events exceeds the displayable content of the interface, supporting gesture sliding to view more alarm events.

Referring to fig. 10, fig. 10 is a graphical user interface for a review of alarm event details provided herein. Upon selection of any one of the alarm event content display areas 301 of FIG. 9, the display interface of FIG. 9 jumps to the display interface of FIG. 10. The alarm event detail interface comprises: a waveform display area 401, a second physiological parameter area 402, an alarm list entry 403, a parameter progress bar 404, and an alarm event information area 405.

The waveform display area 401 is used for loading parameter waveforms stored by alarm events and providing visual waveform trend; the second physiological parameter area 402 is used for displaying all physiological parameter values of the monitor at the moment of alarm occurrence; the alarm list entry 403 is used for providing a function entry for quickly jumping to an alarm review list page, so as to meet the requirements of users for switching and viewing different alarm events; the parameter progress bar 404 is used to indicate the current physiological parameter viewing progress; the alarm event information area 405 is used to display the current alarm event name and alarm event. The alarm event name, alarm time are displayed in an alarm event information area 405 at the top of the interface. The user can view the complete alarm waveform segment in the waveform display area 401 through a swipe gesture, and the waveform duration can be 8 seconds, 16 seconds or 32 seconds, which is selected by the user. The second physiological parameter area 402 displays all physiological parameters at the time of alarm occurrence in the form of a unit block, and causes the physiological parameter of alarm occurrence to be fixed and located at the first place of the parameter area, and to be highlighted, wherein the display forms include but are not limited to: font bolding, color variation, marking symbols. When multiple physiological alarms occur at the same time, physiological parameter values of other physiological alarms are also highlighted. The second physiological parameter area 402 supports gesture swipes to view more physiological parameter values, and the parameter progress bar 404 synchronously displays the parameter swipe progress. The alarm event detail page provides three jump page entries: a waveform display area 401, a second physiological parameter area 402, an alarm list entry 403, and a jump function is performed in response using a specific gesture of action, including but not limited to a click, a long press, a double click.

In order to clearly illustrate the whole implementation process of the invention, the whole flow of physiological parameter trend/holographic waveform review and alarm event review is introduced below, the system acquires physiological parameter values and waveforms in the monitoring process in real time and stores the physiological parameter values and waveforms in a fixed format in a system data storage module, records alarm occurrence time, type and alarm parameter threshold values, and establishes correlation between parameter data and alarm events in time dimension to provide a basis for data review and alarm event review.

Based on the above-described fig. 7 to 10, a specific overall implementation procedure will be described.

Specifically, in response to a view instruction to one of the first alarm event markers 102 or the second alarm event markers 205, a note pop-up window is displayed that describes the underlying content of the alarm event.

Before loading the trend review page, the system of the monitor reads the monitoring data and the alarm data in the current patient data file, retrieves the alarm time and the alarm grade of each alarm item in the alarm data file, and establishes time connection with the physiological data of the patient. Patient data and alarm event icons are loaded according to the window time resolution respectively. When receiving an instruction for previewing a certain alarm event, retrieving the alarm event according to the time positioning and the subordinate parameters of the alarm icon, and obtaining the basic content of the alarm event, wherein the method comprises the following steps: alarm content, alarm triggering condition, alarm starting time and alarm ending time, and displaying alarm information in a note popup window in a text mode.

Wherein, before loading the displayed holographic waveform interface, the system identifies the location of the review progress adjustment block 203 in the second review progress bar 202, reads waveform data and alarm data within a fixed time period within the current patient data file, retrieves the alarm time and alarm level of each alarm entry in the alarm data file, and establishes a temporal relationship with the patient waveform data. The system automatically positions the alarm event icons in the waveform display areas of the corresponding parameters, and parameter waveforms in the interval from the alarm starting time to the alarm ending time are marked with the same color as the alarm level, such as low-level, medium-level marks as yellow and high-level alarms as red. When an instruction for previewing a certain alarm event is received, the alarm event is searched according to the time positioning and the subordinate parameters of the alarm icon, the basic content of the alarm event is obtained, and the tag content comprises: alarm level, alarm event name, alarm triggering condition, alarm starting time, alarm ending time and similar alarm event statistics. Wherein the statistical interval is a full time period, and the statistical content is the same type of physiological alarm times. The alarm event statistics are displayed in a form of a chart including but not limited to words, histograms, pie charts and the like.

And receiving an instruction of clicking to check the details of the alarm event in the note popup window, and jumping to the page of the details of the alarm event.

And manually triggering and checking an alarm detail instruction in the note popup window area, and jumping to an alarm event detail interface. Loading detailed information of the alarm event: comprising the following steps: alarm level, alarm content, alarm triggering condition, alarm time, all physiological parameter values at alarm occurrence time and 16s physiological parameter waveforms before and after alarm occurrence. The waveform data of the front and rear 16s physiological parameters calculate the duration of the waveform segment according to the alarm starting time, and the holographic waveform segment of the related physiological parameters is intercepted.

And receiving an instruction for jumping the trend chart on the alarm event detail page, and jumping to a trend chart interface or a holographic waveform interface at the alarm moment.

And jumping to a trend chart interface of the alarm time.

A second physiological parameter area 402 within the alarm event detail interface provides access to the jump trend graph function. After a user manually triggers any unit block of the physiological parameter area to generate an instruction of jumping the trend chart, the system rapidly positions and acquires monitoring data in 1/2 of window time before and after the alarm time according to the alarm time of the current alarm event, and loads and displays the monitoring data in a trend review window. The first physiological parameter area 103 and the parameter trend waveform 104 load the parameter values and trend curves of the alarm subordinate parameters first, and review the quick positioning of the first cursor 111 to the alarm occurrence time.

The waveform review section 201 within the alarm event detail page provides an entry to the jump holographic waveform interface. The user manually triggers an instruction for generating a jump holographic waveform in the waveform review area, the system acquires a parameter waveform within the time length from the forward pushing 16s of the alarm starting moment to the window time setting 206 according to the alarm starting time of the current alarm event and the subordinate alarm physiological parameters, loads the first line waveform area displayed in the waveform display area 401, and rapidly positions the second cursor 204 to the alarm starting moment.

The monitor system acquires physiological parameter values and waveforms in the monitoring process in real time and stores the physiological parameter values and waveforms in a fixed format in a system data storage module, records alarm occurrence time, alarm type and alarm parameter threshold values, establishes correlation between parameter data and alarm events in time dimension, and provides a basis for data review and alarm event review.

Referring to fig. 11, fig. 11 is a schematic structural diagram of an embodiment of a monitor provided in the present application. The monitor 500 includes a processor 501, and a memory 502 and a display screen 503 coupled to the processor 501, wherein the memory 502 stores a computer program, and the processor 501 is configured to execute the computer program to implement the following method:

Displaying a monitoring interface, wherein the monitoring interface is used for displaying historical physiological data of a monitored person; and responding to a viewing instruction aiming at the alarm event mark on the monitoring interface, and jumping to a data analysis interface corresponding to the alarm event mark, wherein the alarm event mark is obtained by marking abnormal data in the historical physiological data.

It will be appreciated that the processor 501 is further configured to execute a computer program to implement the method of any of the above embodiments, and specific reference to any of the above embodiments is omitted here.

Referring to fig. 12, fig. 12 is a schematic structural diagram of an embodiment of a computer readable storage medium provided in the present application. The computer readable storage medium 600 stores a computer program 601, which when executed by a processor, implements the method of:

displaying a monitoring interface, wherein the monitoring interface is used for displaying historical physiological data of a monitored person; and responding to a viewing instruction aiming at the alarm event mark on the monitoring interface, and jumping to a data analysis interface corresponding to the alarm event mark, wherein the alarm event mark is obtained by marking abnormal data in the historical physiological data.

It will be appreciated that the computer program 601, when executed by a processor, is further configured to implement the method of any of the above embodiments, and specific reference to any of the above embodiments is omitted here.

In summary, the method for reviewing a monitor provided in the present application includes: displaying a monitoring interface, wherein the monitoring interface is used for displaying historical physiological data of a monitored person; and responding to a viewing instruction aiming at the alarm event mark on the monitoring interface, and jumping to a data analysis interface corresponding to the alarm event mark, wherein the alarm event mark is obtained by marking abnormal data in the historical physiological data. Through the mode, the alarm event mark is associated with the data analysis interface, so that a user can directly operate the alarm event mark to jump to the data analysis interface corresponding to the abnormal data, the operation flow of the user during abnormal review is reduced, the viewing efficiency of the abnormal data is improved, and the user experience is improved.

And displaying alarm event marks on a trend review interface and a holographic waveform interface, and providing the functions of previewing alarm event details and jumping the alarm event detail interface. Meanwhile, in the alarm event detail interface, an alarm event waveform jump holographic waveform page and a trend review page at the jump positioning moment are also provided. And establishing a connection between the alarm event and the physiological data and between the alarm event and the waveform data in the time dimension, wherein the alarm event only stores text information such as alarm content, alarm grade, alarm occurrence time and the like, so that the problem of redundancy of the independent storage data of the alarm event is solved, the storage space is saved, and an operator is assisted to quickly locate the alarm event.

In the several embodiments provided in the present application, it should be understood that the disclosed methods and apparatuses may be implemented in other manners. For example, the above-described device embodiments are merely illustrative, e.g., the division of the modules or units is merely a logical functional division, and there may be additional divisions when actually implemented, e.g., multiple units or components may be combined or integrated into another system, or some features may be omitted, or not performed.

The units described as separate units may or may not be physically separate, and units shown as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the embodiment.

In addition, each functional unit in each embodiment of the present application may be integrated into one processing unit, each unit may exist alone physically, or two or more units may be integrated into one unit. The integrated units may be implemented in hardware or in software functional units.

The integrated units of the other embodiments described above may be stored in a computer readable storage medium if implemented in the form of software functional units and sold or used as stand alone products. Based on such understanding, the technical solution of the present application may be embodied in essence or a part contributing to the prior art or all or part of the technical solution, in the form of a software product stored in a storage medium, including several instructions to cause a computer device (which may be a personal computer, a server, or a network device, etc.) or a processor (processor) to perform all or part of the steps of the methods described in the embodiments of the present application. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a magnetic disk, or an optical disk, or other various media capable of storing program codes.

The foregoing description is only of embodiments of the present application, and is not intended to limit the scope of the patent application, and all equivalent structures or equivalent processes using the descriptions and the contents of the present application or other related technical fields are included in the scope of the patent application.

Claims (11)

1. A method of reviewing a monitor, the method comprising:

displaying a monitoring interface, wherein the monitoring interface is used for displaying historical physiological data of a monitored person;

in response to a view instruction for an alarm event marker on the monitoring interface, jumping to a data analysis interface corresponding to the alarm event marker,

wherein the alarm event signature is based on marking abnormal data in the historical physiological data.

2. The method according to claim 1, wherein the data analysis interface is provided with a data display area for displaying all physiological data acquired simultaneously with the abnormal data;

the method further comprises the steps of:

and responding to a viewing instruction for the data display area, and jumping to the monitoring interface.

3. The method of claim 2, wherein the monitoring interface is a trend review interface and the data analysis interface is an alarm event detail interface;

the display monitoring interface comprises:

displaying the trend review interface;

the responding to the checking instruction for the alarm event mark on the monitoring interface jumps to the data analysis interface corresponding to the alarm event mark, and comprises the following steps:

Responding to a viewing instruction aiming at the alarm event mark, and jumping to an alarm event detail interface corresponding to the alarm event mark;

the responding to the view instruction for the data display area jumps to the monitoring interface, and comprises the following steps:

and responding to a viewing instruction for the data display area, and jumping to the trend review interface.

4. The method of claim 3, wherein the trend review interface includes a physiological data trend display area and a physiological data value display area; the physiological data trend display area is used for displaying a trend chart of at least one physiological data, and the physiological data numerical value display area is used for displaying physiological data numerical values at appointed moments in the trend chart;

the method further comprises the steps of:

and switching the physiological data displayed in the physiological data value display area in response to a sliding operation for the physiological data value display area, and switching a trend graph in a physiological data trend display area so that the trend graph corresponds to the physiological data displayed in the physiological data value display area.

5. A method according to claim 3, characterized in that the method further comprises:

Responding to an alarm preview instruction on the trend review interface, and displaying all alarm events corresponding to the monitored person;

responding to a checking instruction aiming at a target alarm event in all alarm events, and jumping to an alarm event detail interface corresponding to the target alarm event;

the alarm event detail interface is used for displaying all physiological data acquired simultaneously with the abnormal data, alarm types corresponding to the abnormal data and/or waveforms corresponding to the abnormal data.

6. The method of claim 1, wherein the monitoring interface displays waveforms corresponding to the historical physiological data; the alarm event markers are located at abnormal wavebands in the waveform;

the response to the viewing instruction for the alarm event mark on the monitoring interface, before jumping to the data analysis interface corresponding to the alarm event mark, comprises:

responding to an alarm preview instruction aiming at the alarm event mark, and displaying a sub display interface; and displaying related information corresponding to the alarm event mark on the sub-display interface, wherein the related information comprises alarm grade, physiological data, event generation time and statistical information of the same type of alarm.

7. The method according to claim 1, wherein the data analysis interface is provided with a waveform display area for displaying a band corresponding to the abnormal data;

the method further comprises the steps of:

and responding to a viewing instruction for the waveform display area, and jumping to the monitoring interface.

8. The method of claim 7, wherein the monitoring interface is a holographic waveform interface and the data analysis interface is an alarm event detail interface;

the display monitoring interface comprises:

displaying the holographic waveform interface;

the responding to the checking instruction for the alarm event mark on the monitoring interface jumps to the data analysis interface corresponding to the alarm event mark, and comprises the following steps:

responding to a viewing instruction aiming at the alarm event mark, and jumping to an alarm event detail interface corresponding to the alarm event mark;

the responding to the view instruction for the waveform display area jumps to the monitoring interface, and comprises the following steps:

and responding to a viewing instruction for the waveform display area, and jumping to the holographic waveform interface.

9. The method of claim 1, wherein the same physiological data displayed by the monitoring interface and the data analysis interface are stored in the same memory space.

10. A monitor comprising a processor and a memory coupled to the processor and a display screen, the memory having a computer program stored therein, the processor being configured to execute the computer program to implement the method of any of claims 1-9.

11. A computer readable storage medium, characterized in that the computer readable storage medium stores a computer program which, when executed by a processor, implements the method according to any of claims 1-9.

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