CN110604580A - Medical equipment, and interval threshold setting method and device for medical equipment - Google Patents

Abstract

The application provides an interval threshold setting method for medical equipment, which can display an interval threshold setting interface, wherein the interface comprises a numerical value track control, different positions of the numerical value track control correspond to numerical values with different sizes, and the numerical value track control is associated with a combined sliding control and is used for executing moving operation on the sliding control.

Description

Medical equipment, and interval threshold setting method and device for medical equipment

Technical Field

The application relates to the technical field of medical equipment, in particular to medical equipment, and a method and a device for setting an interval threshold value of the medical equipment.

Background

In the medical field, the physiological sign state of a patient is often required to be monitored, and if the physiological sign state of the patient is found to be poor, the patient is timely treated; of course, if the physiological sign state of the patient is good, the physiological sign state can be fed back to the medical staff positively, so that auxiliary information can be provided for the follow-up medical treatment of the medical staff.

The physiological sign state monitoring process mainly comprises the steps of collecting physiological sign parameter values of a patient, determining the state interval within which the physiological sign parameter values are contained, and determining the state represented by the state interval as the current physiological sign state of the patient.

As can be understood from the above monitoring process, in order to implement the physiological sign status monitoring, a numerical range of the status interval needs to be preset.

Disclosure of Invention

In a first aspect, the present application provides a method for setting an interval threshold for a medical device, comprising:

displaying an interval threshold setting interface, wherein the setting interface comprises numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and at least one pair of sliding controls with a preset combination relation are associated with the numerical value track controls;

responding to the movement operation of a user on at least one sliding control, moving the sliding control to a target position indicated by the movement operation on the numerical track control, and displaying the numerical value of the sliding control at the target position;

the numerical value ranges corresponding to the pair of sliding controls are used for forming a state interval.

In a second aspect, the present application provides a section threshold setting method for a medical device, including:

displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises a plurality of numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and the numerical value track controls are associated with a pair of sliding controls with a preset combination relation;

responding to the movement operation of a user on any sliding control on any numerical track control, moving the sliding control to a target position indicated by the movement operation on the numerical track control, and displaying the numerical value of the sliding control at the target position;

and the numerical ranges corresponding to the pair of sliding controls on the same numerical track control are used for forming a state interval.

In a third aspect, the present application provides an interval threshold setting apparatus for a medical device, comprising:

the first setting interface display module is used for displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and at least one pair of sliding controls with a preset combination relation are associated with the numerical value track controls;

the first sliding control moving module responds to the moving operation of a user on at least one sliding control, moves the sliding control to the target position indicated by the moving operation on the numerical track control, and displays the numerical value of the sliding control at the target position;

the numerical value ranges corresponding to the pair of sliding controls are used for forming a state interval.

In a fourth aspect, the present application provides an interval threshold setting apparatus for a medical device, comprising:

the second setting interface display module is used for displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises a plurality of numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and the numerical value track controls are associated with a pair of sliding controls with a preset combination relation;

the second sliding control moving module is used for responding to the moving operation of a user on any sliding control on any numerical track control, moving the sliding control to the target position indicated by the numerical track control through the moving operation, and displaying the numerical value of the sliding control at the target position;

and the numerical ranges corresponding to the pair of sliding controls on the same numerical track control are used for forming a state interval.

In a fifth aspect, the present application provides a medical device comprising:

the display is used for displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and the numerical value track controls are associated with at least one pair of sliding controls with a preset combination relation;

the processor responds to the movement operation of a user on at least one sliding control, moves the sliding control to the target position indicated by the movement operation on the numerical track control, and displays the numerical value of the sliding control at the target position;

the numerical value ranges corresponding to the pair of sliding controls are used for forming a state interval.

In a sixth aspect, the present application provides a medical device comprising:

the display is used for displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises a plurality of numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and a pair of sliding controls with a preset combination relation are associated with the numerical value track controls;

the processor responds to the movement operation of a user on any sliding control on any numerical track control, moves the sliding control to the target position indicated by the movement operation on the numerical track control, and displays the numerical value of the sliding control at the target position;

and the numerical ranges corresponding to the pair of sliding controls on the same numerical track control are used for forming a state interval.

In a seventh aspect, the present application provides a readable storage medium having stored thereon a computer program which, when executed by a processor, implements the method described above.

In an eighth aspect, the present application provides a readable storage medium having stored thereon a computer program which, when executed by a processor, implements the method described above.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a flow chart of a method for interval threshold setting for a medical device;

FIGS. 2A-2H are several exemplary diagrams of an interval threshold device interface;

FIG. 3 is another flow chart of an interval threshold setting method for a medical device;

FIGS. 4A-4B are two additional exemplary diagrams of an interval threshold device interface;

fig. 5 and 6 are two structural examples of the interval threshold setting device for the medical apparatus;

fig. 7 is a diagram of an exemplary monitor structure.

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, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In order to monitor the patient, the medical device sets different state intervals for different physiological sign parameters, and the different state intervals represent different sign states. After the medical equipment obtains the physiological sign parameter value of the patient, the physical sign state of the patient is determined by judging which state interval the physical sign parameter value falls into. Or some state intervals belong to alarm intervals, and when the monitored physiological sign parameters are located in the alarm intervals, alarm prompt is carried out. Alternatively, the historical data of a certain physiological sign parameter needs to be counted in a segmented manner, and the statistics are performed based on one or more set state intervals.

The application provides a method for setting an interval threshold value of medical equipment, so that users such as medical staff can freely and flexibly set a numerical range corresponding to a state interval according to monitoring requirements.

Referring to fig. 1, a flow of an interval threshold setting method for a medical apparatus is shown. As shown in fig. 1, the process may specifically include steps 1.1-1.2.

Step 1.1: and displaying an interval threshold setting interface.

The medical device has a display screen displaying a setting interface for a user to set a value range of the state interval, and thus may be referred to as an interval threshold setting interface.

The setting interface comprises a numerical value track control, and numerical values with different sizes correspond to different positions of the numerical value track control. The numerical value represented by the numerical value track control can be a continuous numerical value or a discontinuous numerical value. The numerical values may or may not be evenly distributed on the numerical orbit control. To prompt the user, the values may be displayed in a settings interface.

The numerical value represented by the numerical value track control is the physiological sign parameter value of the subject monitored by the medical equipment. It should be noted that the parameter values are not values acquired by the medical device in real time, but values that are recognized by medical standards as being likely to appear in such subjects. The method can be applied to any scene, and in different application scenes, the physiological sign parameter value range of the monitored object is different, so the numerical value represented by the numerical track control is set according to the application scenes.

For example, assuming that the method sets the state interval for monitoring the blood oxygen saturation level of the person, it can be known that the blood oxygen saturation level of the person may occur in a range of 0-100%, and thus the numerical orbit control represents a range of 0-100%, or other ranges within the range, such as 10% -100%, depending on the monitoring requirements.

As another example, assuming that the state interval set by the method is used for monitoring the body temperature of a person, it can be known that the body temperature range that the person may have is 34 ℃ to 43 ℃, and thus the numerical track control represents a numerical range of 34 ℃ to 43 ℃, or other ranges within the range according to the monitoring requirement.

Based on the above description, the numerical segment represented by the numerical track control may be any range.

At least one pair of sliding controls are associated with the numerical track control, a preset combination relationship exists between the pair of sliding controls, and the pair of sliding controls with the combination relationship is used for limiting a state interval range. Specifically, the sliding control may slide on the numerical track control, and the numerical value corresponding to the position to which the sliding control slides, that is, the range threshold value representing the state interval.

For example, if the position value to which a certain slide control slides is 40, and the position value to which another slide control having a corresponding relationship with the slide control slides is 70, the range of the state interval value represented by the pair of slide controls is 40 to 70.

It should be noted that, the combination relationship of the sliding control indicates that the numerical values at the positions corresponding to the sliding control have a combination relationship, and the numerical values having the combination relationship are used to form the state interval. Conversely, two numerical thresholds must be used in order to be able to represent a state interval. The same sliding component can have corresponding relation with a plurality of different sliding components, or can have different combination relations corresponding to two different sliding components.

The combination relation of the sliding control can be recorded in an associated storage module of the medical device, and can also be displayed in a setting interface through marks. The marking mode can be a text indication, a picture indication or a homochromatic mark.

Specifically, one way of text indication is to add text information to the sliding control with the combination relationship, where the text information is used to indicate that the pair of sliding controls has the combination relationship; the picture indication and the character indication are the same; one way to mark the same color is to add the same color to the sliding controls with the combination relationship, and add different colors to the sliding controls with different combination relationships for differentiation.

The shape of the numeric track control may be various, such as a straight bar, a bar with a radian, and the like, and the present application is not limited specifically. The form of the slide control may be various, and the present application is not particularly limited.

Step 1.2: and responding to the movement operation of the user on at least one sliding control, moving the sliding control to the target position indicated by the movement operation on the numerical track control, and displaying the numerical value of the sliding control at the target position.

In order to implement touch operation, the display screen may be set as a screen with a touch function. After the setting interface is displayed on the display screen, the user can move the sliding control on the numerical track control. Of course, the method also comprises the step of realizing the sliding control operation of the control through non-contact gesture recognition.

Along with the moving operation of a user on a certain sliding control, the method slides the sliding control to the position indicated by the moving operation, wherein the position refers to the cut-off position of the moving operation. For convenience of description, the location may also be referred to as a target location.

The user can simultaneously move one or more sliding controls, and the moved sliding control can be any sliding control on the numerical track control.

It should be noted that, a sliding control may be added to the starting position where the numeric track control can represent the numeric value, the sliding control defaults to a fixed sliding control and cannot be moved by the user, and the numeric value corresponding to the fixed sliding control is the starting value of the numeric range represented by the numeric track control. Similarly, a fixed sliding control may be set at a cut-off position where the numerical track control can represent a numerical value, where the numerical value corresponding to the fixed sliding control is a cut-off value of the numerical value range represented by the numerical track control. The two fixed sliding controls are sliding controls which cannot be touch-operated by a user.

If the sliding controls corresponding to the first position and the last position are fixed sliding controls, the sliding controls may be displayed in the setting interface or may not be displayed in the setting interface.

It should be noted that a slider control that is paired with a slider control group may not be displayed. For example, the sliding control of a certain sliding control group pair is a sliding control corresponding to the start position or the end position of the numeric track control, and the sliding control corresponding to the start position or the end position may be a fixed control and may not be displayed in the interval threshold setting interface.

After the sliding control moves to the target position, the numerical value corresponding to the sliding control at the target position can be displayed on the setting interface. The slider control may be a graphical control that occupies a certain area, in which case the numerical value may be displayed inside the slider control or may be displayed outside the slider control.

It can be known that different positions of the numerical track control represent different numerical values, and in order to prompt the user of numerical information passing through the sliding process, the numerical value of the position where the sliding control slides is displayed in real time along with the operation of the user for moving the sliding control.

For example, the numerical value represented by the numerical track control is a continuous integer, and assuming that the user moves the slide control from the position corresponding to the numerical value 20 to the position corresponding to the numerical value 25, the changing values of the numerical values 20, 21, 22, 23, 24, and 25 may be displayed on the slide control during the movement. And when the sliding control stops at the position corresponding to the numerical value 25, the numerical value 25 is displayed on the sliding control.

The numerical value ranges corresponding to the pair of sliding controls are used for forming a state interval.

It should be noted that the state interval can be explicitly represented on the numeric track control.

One implementation may be that a pair of numeric track controls covered by a sliding control with a combination relationship are filled with colors, and different state intervals are filled with different colors for distinction. Another implementation manner may be to add an explanatory text at a position corresponding to the state interval to indicate which state the state corresponding to the state interval is. Another implementation manner is that a state flag is added to the sliding control for forming the state interval, the state flag is displayed at a corresponding position of the sliding control, and the corresponding position is only enough to prompt the user that the state flag corresponds to the sliding control. It should be noted that any of the three implementations may be used in combination.

It should be noted that the state interval may be used for other functional modules of the medical device to implement corresponding functions.

In one application example, the state interval may be an alarm interval. For example, if the medical device monitors that the physiological sign parameter value of a certain subject falls within a range of a certain alarm interval, an alarm prompt is performed on the physiological sign parameter value.

In another application example, the state interval may be a statistical interval. For example, the medical device may count the proportion of physiological sign parameter values falling into each statistical interval in a period of time of the monitored object based on the set statistical interval, and each counted proportion may be used as an index for medical staff to determine the health condition of the monitored object.

In yet another application, the status interval may be used as a treatment interval. For example, to determine the therapeutic effect of a certain disease, a medical care professional may use the medical device provided in the present application to set a numerical range of a treatment interval corresponding to a physiological parameter that can reflect the therapeutic effect. During the monitoring process, the medical device judges whether the parameter value of the physiological sign parameter of the treatment object can fall into the treatment interval, so as to determine whether the treatment process achieves the expected treatment effect.

Of course, the above application examples are only examples, and the set state interval may be applied to various functional modules according to actual requirements.

According to the technical scheme, the interval threshold setting method for the medical equipment can display an interval threshold setting interface, the interface comprises numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, the numerical value track controls are associated with combined sliding controls and used for executing moving operation on the sliding controls, the medical equipment moves the sliding controls to target positions indicated by the moving operation based on the moving operation of a user and can display the numerical values corresponding to the target positions, so that the numerical value ranges corresponding to a pair of sliding controls with a combination relation can form a state interval, and the state interval can provide data support for realizing functions of monitoring and the like of the medical equipment.

In order to facilitate understanding of the implementation process of the above interval threshold setting method, a specific example is provided below for explanation.

See FIG. 2A, which illustrates one implementation of an interval threshold setting interface.

As shown in fig. 2A, the shape of the numerical trajectory control included in the setting interface is a straight bar, and the whole position corresponds to a numerical value, and assuming that in an application scenario of monitoring blood oxygen saturation, the range of the numerical value of blood oxygen saturation is 0-100, the numerical values 0-100 are uniformly distributed in the whole position of the numerical trajectory control. In order to simplify the content of the setting interface and facilitate the user operation, the numerical track control only displays the numerical values corresponding to the starting position and the ending position, that is, the numerical value corresponding to the starting position is 0, and the numerical value corresponding to the ending position is 100.

The numerical value track control is provided with a plurality of circular sliding controls, and every two sliding controls have a combined relation. The combination relation of the sliding control can be seen from the display style of the sliding component.

As shown in fig. 2A, counting from left to right, the first slider control has a combination relationship with the second slider control, the second slider control has a combination relationship with the third slider control, and the third slider control has a combination relationship with the fourth slider control.

The state section represented by the first pair of sliding controls can be referred to as a first state section, and one application scenario is that the state section can be used in a low-value alarm function of a medical device, and if the value of the blood oxygen saturation level of the monitored object falls within the state section, the medical device can perform a low-value alarm prompt to prompt a medical worker that the blood oxygen saturation level of the monitored object is too low. As shown in fig. 2A, in order to prompt the application of the state section in the scene, a bubble prompt may be displayed on the associated slide control, which prompts a "low alarm first threshold" and a "low alarm second threshold".

The state interval represented by the second pair of sliding controls may be referred to as a second state interval, and one application scenario is that the state interval may be used in a therapy monitoring function of a medical device, for example, in a therapy process of a certain subject, after a therapy means needs to be monitored, whether blood oxygen saturation enters the state interval or not. As shown in fig. 2A, to indicate the application of the state interval in the scene, a bubble indication may be displayed on the associated slider control, indicating "target low threshold" and "target high threshold".

The state section represented by the third pair of sliding controls can be referred to as a third state section, and one application scenario is that the medical device can be used in a high numerical value alarm function of the medical device, and if the value of the blood oxygen saturation degree of the monitored object falls into the state section, the medical device can perform high numerical value alarm prompt to prompt medical staff that the blood oxygen saturation degree of the monitored object is too high. As shown in fig. 2A, in order to prompt the application of the state section in the scene, a bubble prompt may be displayed on the associated slide control, which prompts a "high alarm first threshold" and a "high alarm second threshold".

In the above three cases, the bubble indication containing the text can be regarded as a specific implementation manner of the above-mentioned status flag.

In practical applications, as shown in fig. 2B, in order to set a numerical range of a certain state interval, a user may drag a sliding control corresponding to the state interval on a numerical track control. And the sliding control slides on the numerical track control, slides to different positions and displays different numerical values.

The scheme implementation is explained based on the numerical track control and the sliding control shown in fig. 2A.

For example, the numeric track control can be positioned horizontally, vertically, or at other angles. In addition, the numerical track control is not limited to a bar shape, and may be an annular shape, an arc shape, or the like, and the radian is not particularly limited.

The specific form of the sliding control is not limited to a circle, and may be other shapes, such as a square, a triangle, a diamond, and the like. The numerical value corresponding to the sliding control is not limited to be displayed inside the sliding control, but may also be in an associated position of the sliding control, such as a nearby position of the sliding control, which, of course, needs to be able to indicate that the numerical value is associated with the sliding control.

The numeric track control can represent a numeric value using a partial position of the control, that is, the numeric start value can not correspond to the start position of the numeric track control, or the numeric cutoff value can not correspond to the cutoff position of the numeric track control, or a combination of both.

The state intervals formed by the sliding controls can have intervals and are not limited to being connected. For example, as shown in fig. 2C, the interval threshold setting interface includes a numeric track control, the numeric track control includes two state intervals, where the sliding control a and the sliding control B form one state interval, and the sliding control C and the sliding control D form another state interval. It should be noted that there is no state interval between the slider control B and the slider control C.

The number of the slide controls can also be set by the user, setting operations such as adding, deleting, and modifying. The present application provides five implementations as follows.

A first implementation comprises the following steps 2.1-2.3.

Step 2.1: displaying a first setup button, the first setup button including functionality to add and/or delete a slider control.

The first setting button may include a plurality of setting buttons, and different setting buttons have different functions. For example, the section threshold setting interface includes two first setting buttons, and the first setting buttons respectively display characters for addition and deletion.

Step 2.2: and adding a sliding control at any position of the numerical track control in response to the adding function selected by the user on the first setting button.

When a user needs to add a sliding control, the adding function of the first setting button can be triggered, and therefore the sliding control is added to any position of the numerical track control of the medical equipment. The arbitrary position may be a position corresponding to a calculated random value.

Step 2.3: and in response to the user selecting the operation of the sliding control on the numerical track control and the deletion function selected on the first setting button, deleting the selected sliding control from the numerical track control.

If a user wants to delete an existing sliding control, the user can select the sliding control on the numerical track control, select operation such as clicking the sliding control, and select a deletion function of the first setting button, so that deletion of the sliding control is achieved. It should be noted that the order of selecting the slide control and selecting the button function is not limited to the above, and may be the reverse order.

A second implementation comprises the following steps 3.1-3.2.

Step 3.1: and in response to a delete click operation performed by a user on the slide control on the numerical track control, deleting the slide control from the numerical track control.

When a user wants to delete a certain sliding control, the user can directly execute a click operation corresponding to the deletion function on the sliding control, such as double click, and the medical device deletes the sliding control based on the click operation.

Step 3.2: and adding a sliding control on the numerical track control in response to the clicking operation of the user on the numerical track control for adding the sliding control.

When a user wants to delete a certain sliding control, a click operation corresponding to the function addition can be directly executed at a certain position of the sliding track control, such as clicking, and the medical device adds the sliding control at the position based on the click operation.

A third implementation comprises the following steps 4.1-4.3.

Step 4.1: and providing a selection menu in response to the clicking operation performed by the user on the interval threshold setting interface, wherein the selection menu comprises an addition and/or deletion option.

The click operation performed by the user may be performed at any position of the setting interface, or at a specific position, for example, a click operation is performed on a certain slide control, or a click operation is performed at a certain position of a numerical track control.

Based on the clicking operation of the user, the medical device provides a selection menu, the selection menu can provide addition and deletion options at the same time, and can also only contain the addition option or only contain the deletion option based on different triggering modes of the user.

As shown in fig. 2D, if the user wants to add a slide control, a single-click operation may be performed on the numeric track control, and the medical device displays a selection menu near the location. The selection menu contains an add option, the user clicks the add option, and the medical device adds a slider control based on the operation.

As shown in fig. 2D, if the user wants to delete a certain sliding control, the user may press the sliding control, and after the pressing reaches a preset time threshold, a selection menu is displayed near the sliding control in the setting interface. The selection menu comprises a deletion option, the user clicks the deletion option, and the medical device deletes the pressed sliding control based on the operation.

Step 4.2: a slider control is added to the numeric track control in response to the user selecting an add option in the selection menu.

Step 4.3: in response to a user selecting a slider control on the numeric track control and a delete option selected on the selection menu, the selected slider control is deleted from the numeric track control.

In a scene that a user wants to delete a certain sliding control, if the triggering mode of the selection menu is not based on the clicking operation of the user on the certain sliding control, the selection menu is displayed and contains deletion selection, the user needs to select the sliding control needing to be deleted on the numerical track control, and the medical equipment deletes the sliding control.

It should be noted that, no matter how to add the slide controls, the adding manner may be one at a time, or multiple slide controls may be added at the same time, for example, a pair of slide controls may be added at the same time.

A fourth implementation comprises the following step 5.1. It should be noted that the fourth and fifth implementations merely implement how to delete the slider control.

Step 5.1: in response to a user moving a slider control to an overlapping position of another slider control on the numeric track control, deleting the slider control from the numeric track control.

If the user wants to delete a certain slide control, the user can overlap the slide control with another slide control, such as an adjacent slide control. The overlapping position of the two sliding controls may be a position interval range, and as long as the position interval between the two sliding controls is within the position interval range, the two sliding controls are considered to overlap.

Based on the overlapping operation of the user, the medical device deletes the sliding control slid by the user. Specific implementation procedures can refer to fig. 2E, as shown in fig. 2E, if the user overlaps the second slide control with the third slide control, the second slide control is deleted, which is shown by using a dotted line to indicate that the slide control is deleted.

A fifth implementation comprises the following step 6.1.

Step 6.1: and in response to the user moving a certain sliding control to a direction far away from the numerical track control, deleting the certain sliding control from the numerical track control.

If the user wants to delete a certain sliding control, the user can also move the sliding control to make the sliding control separate from the numerical track control. It will be appreciated that, in order to disengage the slide control from the numeric track control, the direction of movement of the slide control is away from the numeric track control, for example, the direction may be along the slide track control, or the direction may be a direction having an angle with the slide track control.

As shown in fig. 2F, the sliding control is moved along a direction having a certain included angle with the direction of the sliding track control, and when the sliding control is separated from the sliding track control by a certain distance, the medical device may delete the sliding control, as shown in fig. 2F, the sliding control is deleted by using a dotted line.

Four different arrangements of the sliding control are provided above, and of course, in practical applications, other implementations that can be envisioned by those skilled in the art are also possible.

No matter what method is used to add the sliding control, after the newly added sliding control, the method may further include a step of adding a state identifier to the sliding control, specifically:

and responding to the state mark input by the user for the newly added sliding control, and establishing the corresponding relation between the newly added sliding control and the input state mark.

And the state identification is used for indicating the action of the numerical value corresponding to the sliding control in the formed state interval. For example, in the example of fig. 2A, the state "target low threshold" identifies the corresponding numerical value of the corresponding slider control, which represents the lowest value of the state interval of the treatment target; the state of "target high threshold" identifies the corresponding numerical value of the corresponding slide control, and represents the highest value of the state interval of the treatment target.

The user can input the state mark for the newly added sliding control, and the input mode can comprise multiple modes. For example, the user double-clicks the newly added slider control, displays a bubble box at a position near the slider control, and the user can input a status flag in the bubble box. As another example, the setup interface may provide a fixed input area within which the user selects the newly added slider control and then enters the status flag.

The input of the status flag may be a specific implementation of selection input, that is, a selection item of the status flag may be provided for the user, the user selects a certain required status flag item in the selection item, and the medical device inputs the status flag item selected by the user based on the selection operation of the user.

Based on the input status flag, the medical device establishes a corresponding relationship between the status flag and the newly added sliding control. The status flag input by the user may be displayed on the section threshold setting interface, or may not be displayed on the section threshold setting interface.

Besides adding the state flag to the newly added sliding control, the combination relationship of the sliding control can be reset after the sliding control is newly added or deleted. Specifically, the method comprises the following steps:

if the sliding control is added, establishing a combination relation for the added sliding control and other sliding controls; and if the sliding control is deleted, establishing a new combination relation for the sliding control with the preset combination relation with the deleted sliding control.

Wherein the added slider control can include, but is not limited to, the following two cases.

First, if there is one additional slide control, a combination relationship between the additional slide control and the adjacent slide control may be established. If the adjacent sliding control is one, establishing a combination relation with the sliding control; and if the number of the adjacent sliding controls is two, establishing a combined relation with the two sliding controls respectively. It can be understood that, since the numerical values corresponding to the two sliding controls having the combination relationship are used for representing the state intervals, establishing a combination relationship is equivalent to adding one state interval.

For example, referring to fig. 2G, suppose that a new sliding control is added on the basis of the sliding control shown in fig. 2A, the new sliding control is represented by a thick line, and a combination relationship between the new sliding control and the left and right sliding controls needs to be established respectively.

And secondly, the two added sliding controls are preset with a combination relationship, and the combination relationship of the two sliding controls is directly recorded.

For example, referring to fig. 2H, it is assumed that a pair of slide controls, including slide control E and slide control F, is added to the pair of slide controls shown in fig. 2C. If the two newly-added sliding controls are sliding control pairs with a combination relationship in advance, the combination relationship of the two sliding controls can be directly recorded.

The case of deleting the slide control is explained.

If the deleted slide control only has a combination relationship with one slide control and the one slide control does not have a combination relationship with other slide controls, the combination relationship is deleted based on the deleted slide control, and the one slide control can also be deleted.

Taking fig. 2C as an example, assuming that the sliding control a is deleted, since the sliding control a only has a combination relationship with the sliding control B, and the sliding control B only has a combination relationship with the sliding control a, based on the operation of deleting the sliding control a, the combination relationship between the sliding control a and the sliding control B is deleted, and the sliding control B can be deleted.

If the deleted slide control only has a combination relationship with one slide control and the one slide control also has a combination relationship with other slide controls, based on the deleted slide control, the combination relationship between the deleted slide control and the one slide control may be deleted. In this case, the one slider control and its associated other composition relationship are retained.

Taking fig. 2A as an example, if the first sliding control counted from left to right is deleted, and the sliding control only has a combination relationship with the second sliding control, but the second sliding control also has a combination relationship with the third sliding control, the combination relationship between the first sliding control and the second sliding control is directly deleted, and the second sliding control and the combination relationship between the second sliding control and the third sliding control are retained.

If the deleted slide control has a combination relationship with the two slide controls, the combination relationship can be directly established for the two slide assemblies.

Taking fig. 2A as an example, if the second sliding control counted from left to right is deleted, and the sliding control and the left and right sliding controls both have a combined relationship, the combined relationship between the first sliding control and the third sliding control is directly established.

In the above embodiment, the interval threshold setting interface includes only one numerical track control. In practical applications, the interval threshold setting interface may also include a plurality of numerical track controls, which will be described in detail below.

Fig. 3 shows another flow of the interval threshold setting method for a medical device provided in the present application. As shown in fig. 3, the setting method may specifically include steps 7.1 to 7.2.

Step 7.1: and displaying an interval threshold setting interface.

Different from the interval threshold setting interface in the embodiment shown in fig. 1, the setting interface includes a plurality of numerical track controls, and for each numerical track control, different positions correspond to numerical values of different sizes. In the present embodiment, each numerical value track control is associated with only one pair of slide controls having a preset combination relationship. A pair of sliding controls is used to form a state interval, that is, different numeric track controls each correspond to a different state interval.

Step 7.2: and responding to the movement operation of the user on any sliding control on any numerical track control, moving the sliding control to the target position indicated by the numerical track control through the movement operation, and displaying the numerical value of the sliding control at the target position.

A user may perform a moving operation on a sliding control on any one of the numerical track controls, and the moving operation manner may refer to the relevant description in fig. 1, which is not described herein again.

And the numerical ranges corresponding to the pair of sliding controls on the same numerical track control are used for forming a state interval.

Furthermore, the state sections on the numerical track controls are arranged in a back-and-forth connection manner, so that if the slide controls of other numerical track controls are connected before or after the moved slide control, the numerical value corresponding to the connected slide control changes correspondingly with the change of the numerical value corresponding to the moved slide control, and the connected slide control can also slide to the position corresponding to the changed numerical value.

That is to say, when the sliding control on a numerical track control is slid, it is determined whether there is a sliding control on another numerical track control that is linked back and forth with the numerical value corresponding to the sliding control, and if there is a sliding control on another numerical track control, the numerical values corresponding to these linked back and forth sliding controls are also changed. The variation mode is as follows:

and the numerical value corresponding to the moved sliding control is reduced or changed, and the numerical value corresponding to the connected sliding control is reduced or increased. It should be noted that, after the numerical value of the linked slide control changes, the numerical value of the moved slide control changes still has a back-and-forth relationship.

In addition, the interval threshold setting interface may further include at least one status flag option, and in response to an operation of selecting a status flag for a numerical track control by a user, a correspondence between a status interval formed by a slide control of the numerical track control and a status represented by the selected status flag is established. That is, the medical device may provide a plurality of status flag options to the user, and the status flag corresponding to the numeric track control may be selectively set by the user.

To facilitate understanding of the section threshold setting interface provided in the present application, the following description is given by way of example. See FIG. 4A, which shows one example of an interval threshold setting interface.

As shown in fig. 4A, the interval threshold setting interface includes three numerical track controls, each numerical track control includes two sliding controls, and the two sliding controls are used to form a state interval. Each numerical track control corresponds to three status flag options, namely 'low value alarm', 'treatment target' and 'high value alarm'. The user may select the status flag by checking the selection box of the status flag option.

The user can select corresponding state mark options for each numerical track control, and based on the selection of the user, the medical device can determine what state interval is formed by numerical values corresponding to two sliding controls on the numerical track control, so that the corresponding relation between the state interval formed by the sliding controls of the numerical track control and the state represented by the selected state mark is established.

Assuming that the user selects the "treatment target" status flag for the second numerical track control, the medical device may determine the numerical values corresponding to the two sliding controls on the second numerical track control, which constitute the treatment target status interval.

The user may move the slider control on a numerical track control, as shown in fig. 4B, and move the slider control on the first numerical track control from the position with the value of 80 to the position with the value of 85. Because the sliding control on the second numerical track control is numerically linked with the sliding control on the first numerical track control, the sliding control on the second numerical track control changes to the position corresponding to the numerical value 86 based on the movement of the sliding control on the second numerical track control.

Referring to fig. 5, a structural schematic of the interval threshold setting apparatus for a medical device is shown. As shown in fig. 5, the apparatus specifically includes: a first setting interface display module 501 and a first sliding control moving module 502.

The first setting interface display module 501 displays an interval threshold setting interface, where the interval threshold setting interface includes numerical track controls, different positions of the numerical track controls correspond to numerical values of different sizes, and the numerical track controls are associated with at least one pair of sliding controls having a preset combination relationship;

a first sliding control moving module 502, configured to, in response to a user's moving operation on at least one of the sliding controls, move the sliding control to a target position indicated by the moving operation on the numerical track control, and display a numerical value of the sliding control at the target position;

the numerical value ranges corresponding to the pair of sliding controls are used for forming a state interval.

The first setting interface display module 501 and the first sliding control moving module 502 may execute the other steps related to the embodiment shown in fig. 1, and implement the functions corresponding to the other steps.

Fig. 6 shows a schematic configuration of the interval threshold setting apparatus for a medical device. As shown in fig. 6, the apparatus specifically includes: a second setting interface display module 601 and a second sliding control moving module 602.

The second setting interface display module 601 is configured to display an interval threshold setting interface, where the interval threshold setting interface includes a plurality of numerical track controls, different positions of the numerical track controls correspond to numerical values of different sizes, and the numerical track controls are associated with a pair of sliding controls having a preset combination relationship;

a second sliding control moving module 602, configured to, in response to a user's moving operation on any sliding control on any numerical track control, move the sliding control to a target position indicated by the moving operation on the numerical track control, and display a numerical value of the sliding control at the target position;

and the numerical ranges corresponding to the pair of sliding controls on the same numerical track control are used for forming a state interval.

The first setting interface display module 501 and the first sliding control moving module 502 may execute the other steps related to the embodiment shown in fig. 3, and implement the functions corresponding to the other steps.

Each of the aforementioned means or modules for performing the various steps may be stored in one or more of the aforementioned memories, and the aforementioned embodiments are each for implementing the aforementioned medical devices wherein each of the aforementioned functional modules includes a set of instructions for performing the respective step of the aforementioned methods, and the aforementioned modules or programs (i.e., sets of instructions) need not be time-limited to separate software programs, procedures or modules, and thus, in various embodiments, various sub-blocks of these modules may be combined or rearranged, and thus, in some embodiments of the invention, memories may store a subset of the modules or data structures described above.

In addition, the present application also provides a medical device comprising: a display and a processor.

The display is used for displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and the numerical value track controls are associated with at least one pair of sliding controls with a preset combination relation;

the processor responds to the movement operation of a user on at least one sliding control, moves the sliding control to the target position indicated by the movement operation on the numerical track control, and displays the numerical value of the sliding control at the target position;

the numerical value ranges corresponding to the pair of sliding controls are used for forming a state interval.

The display and the processor may perform other steps described above in relation to the embodiment shown in fig. 1, and implement functions corresponding to the other steps.

Moreover, the present application also provides a medical device comprising: a display and a processor.

The display is used for displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises a plurality of numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and a pair of sliding controls with a preset combination relation are associated with the numerical value track controls;

the processor responds to the movement operation of a user on any sliding control on any numerical track control, moves the sliding control to the target position indicated by the movement operation on the numerical track control, and displays the numerical value of the sliding control at the target position;

and the numerical ranges corresponding to the pair of sliding controls on the same numerical track control are used for forming a state interval.

The display and the processor may perform other steps described above in relation to the embodiment shown in fig. 3, and implement functions corresponding to the other steps.

The medical devices mentioned in the present application include a monitor, an invasive/noninvasive ventilator, an anesthesia machine, a defibrillator, a nurse station, a central station, and the like, and may also be a computer terminal or a mobile terminal installed with clinical data monitoring and analyzing software to implement the method provided in the above embodiments. The following embodiments are mainly described by taking a monitor as an example.

One specific example of a monitor is shown in fig. 7. FIG. 7 provides a system diagram of a parameter processing module in a multi-parameter monitor.

The multi-parameter monitor has an independent housing, a sensor interface area is provided on a panel of the housing, in which a plurality of sensor interfaces are integrated, for connecting with external physiological sign parameter sensor accessories 711, and a small-sized IXD display area, a display 718, an input interface circuit 720, an alarm circuit 719 (such as an LED alarm area), and the like are further included on the panel of the housing. The parameter processing module is used for communicating with the host and getting electricity from the host, and is used for an external communication and power interface. The parameter processing module also supports an external parameter insertion module, a plug-in monitor host can be formed by inserting the parameter insertion module and is used as a part of the monitor, the plug-in monitor host can also be connected with the host through a cable, and the external parameter insertion module is used as an external accessory of the monitor. In addition, the multi-parameter monitor includes a memory 717 for storing various data generated during the computer program and related monitoring process.

The internal circuit of the parameter processing module is disposed in the housing, as shown in fig. 7, and includes a signal acquisition circuit 712, a front-end signal processing circuit 713, and a main processor 715, which correspond to at least two physiological parameters.

The main processor 715 may implement the various processing-related steps of the various monitored information display methods described above.

The signal acquisition circuit 712 can be selected from an electrocardiograph circuit, a respiration circuit, a body temperature circuit, a blood oxygen circuit, a non-invasive blood pressure circuit, an invasive blood pressure circuit, etc., the signal acquisition circuits 712 are respectively electrically connected with corresponding sensor interfaces for electrically connecting to the sensor accessories 711 corresponding to different physiological sign parameters, the output end of the signal acquisition circuit is coupled to the front-end signal processor, the communication port of the front-end signal processor is coupled to the main processor, and the main processor is electrically connected with an external communication and power interface.

The various physiological sign parameter measuring circuits can adopt a common circuit in the prior art, a front-end signal processor completes sampling and analog-to-digital conversion of an output signal of a signal acquisition circuit, and outputs a control signal to control a measuring process of a physiological signal, and the parameters include but are not limited to: electrocardio, respiration, body temperature, blood oxygen, noninvasive blood pressure and invasive blood pressure parameters.

The front-end signal processor can be realized by a single chip microcomputer or other semiconductor devices, and can also be realized by an ASIC (application specific integrated circuit) or an FPGA (field programmable gate array). The front-end signal processor may be powered by an isolated power supply, and the sampled data may be sent to the host processor via an isolated communication interface after being simply processed and packaged, e.g., the front-end signal processor circuit may be coupled to the host processor 715 via the isolated power supply and communication interface 714.

The reason that the front-end signal processor is supplied with power by the isolation power supply is that the DC/DC power supply is isolated by the transformer, which plays a role in isolating the patient from the power supply equipment, and mainly aims at: 1. isolating the patient, and floating the application part through an isolation transformer to ensure that the leakage current of the patient is small enough; 2. the voltage or energy when defibrillation or electrotome is applied is prevented from influencing board cards and devices of intermediate circuits such as a main control board and the like (guaranteed by creepage distance and electric clearance).

The main processor completes the calculation of the physiological sign parameters, and sends the calculation results and waveforms of the parameters to a host (such as a host with a display, a PC, a central station, etc.) through an external communication and power interface 716, which may be one or a combination of an Ethernet (Ethernet), a Token Ring (Token Ring), a Token Bus (Token Bus), and a local area network interface composed of a backbone Fiber Distribution Data Interface (FDDI) as these three networks, one or a combination of wireless interfaces such as infrared, bluetooth, wifi, WMTS communication, etc., or one or a combination of wired data connection interfaces such as RS232, USB, etc.

The external communication and power interface 716 may also be one or a combination of a wireless data transmission interface and a wired data transmission interface. The host can be any computer equipment of a host computer of a monitor, an electrocardiograph, an ultrasonic diagnostic apparatus, a computer and the like, and matched software is installed to form the monitor equipment. The host can also be communication equipment such as a mobile phone, and the parameter processing module sends data to the mobile phone supporting Bluetooth communication through the Bluetooth interface to realize remote transmission of the data.

In addition, the present application provides a readable storage medium having stored thereon a computer program which, when executed by a processor, implements the various above-described interval threshold setting methods for a medical device.

Reference is made herein to various exemplary embodiments. However, those skilled in the art will recognize that changes and modifications may be made to the exemplary embodiments without departing from the scope hereof. For example, the various operational steps, as well as the components used to perform the operational steps, may be implemented in differing ways depending upon the particular application or consideration of any number of cost functions associated with operation of the system (e.g., one or more steps may be deleted, modified or incorporated into other steps).

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

Additionally, as will be appreciated by one skilled in the art, the principles herein may be reflected in a computer program product on a computer readable storage medium, which is pre-loaded with computer readable program code. Any tangible, non-transitory computer-readable storage medium may be used, including magnetic storage devices (hard disks, floppy disks, etc.), optical storage devices (CD-ROMs, DVDs, Blu Ray disks, etc.), flash memory, and/or the like. These computer program instructions may be loaded onto a general purpose computer, special purpose computer, or other programmable data processing apparatus to produce a machine, such that the instructions which execute on the computer or other programmable data processing apparatus create means for implementing the functions specified. These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including means for implementing the function specified. The computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified.

The foregoing detailed description has been described with reference to various embodiments. However, one skilled in the art will recognize that various modifications and changes may be made without departing from the scope of the present disclosure. Accordingly, the disclosure is to be considered in an illustrative and not a restrictive sense, and all such modifications are intended to be included within the scope thereof. Also, advantages, other advantages, and solutions to problems have been described above with regard to various embodiments. However, the benefits, advantages, solutions to problems, and any element(s) that may cause any element(s) to occur or become more pronounced are not to be construed as a critical, required, or essential feature or element of any or all the claims. As used herein, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, system, article, or apparatus.

The above examples only show some embodiments, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (20)

1. An interval threshold setting method for a medical apparatus, characterized by comprising:

displaying an interval threshold setting interface, wherein the setting interface comprises numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and at least one pair of sliding controls with a preset combination relation are associated with the numerical value track controls;

responding to the movement operation of a user on at least one sliding control, moving the sliding control to a target position indicated by the movement operation on the numerical track control, and displaying the numerical value of the sliding control at the target position;

the numerical value ranges corresponding to the pair of sliding controls are used for forming a state interval.

2. The interval threshold setting method for a medical apparatus according to claim 1, further comprising:

displaying a first setting button, wherein the first setting button comprises a function of adding and/or deleting a sliding control;

adding a sliding control at any position of the numerical track control in response to the adding function selected by the user on the first setting button;

and in response to the user selecting the operation of the sliding control on the numerical track control and the deletion function selected on the first setting button, deleting the selected sliding control from the numerical track control.

3. The interval threshold setting method for a medical apparatus according to claim 1, further comprising:

deleting the sliding control from the numerical track control in response to a deletion click operation performed by a user on the sliding control on the numerical track control;

and responding to the click operation of a user on the numerical track control to add a sliding control, and adding the sliding control on the numerical track control.

4. The interval threshold setting method for a medical apparatus according to claim 1, further comprising:

responding to click operation executed by a user on the interval threshold value setting interface, and providing a selection menu, wherein the selection menu comprises an addition option and/or a deletion option;

in response to an add option selected by a user in the selection menu, adding a slide control on the numeric track control;

deleting the selected slider control from the numeric track control in response to a user selection of a slider control on the numeric track control and a deletion option selected on the selection menu.

5. The interval threshold setting method for a medical device according to claims 2 to 4, wherein in a case where a slide control is newly added, the method further comprises:

and responding to the state mark input by the user for the newly added sliding control, and establishing the corresponding relation between the newly added sliding control and the input state mark.

6. The interval threshold setting method for a medical device according to claim 1, wherein the slide control has a preset status flag, the method further comprising:

and displaying a state mark corresponding to the sliding control at the corresponding position of the sliding control.

7. The interval threshold setting method for a medical apparatus according to claim 1, further comprising:

deleting a slide control from the numeric track control in response to a user moving the slide control to an overlapping position of another slide control on the numeric track control;

or responding to the operation that a user moves a certain sliding control to the direction far away from the numerical track control, and deleting the certain sliding control from the numerical track control.

8. The interval threshold setting method for a medical apparatus according to any one of claims 2, 3, 4 and 7, characterized by further comprising:

if a sliding control is added, establishing a combined relation for the added sliding control and other sliding controls;

and if the sliding control is deleted, establishing a new combination relation for the sliding control with the preset combination relation with the deleted sliding control.

9. The interval threshold setting method for the medical device according to claim 8, wherein if a sliding control is added, establishing a combined relationship for the added sliding control and other sliding controls comprises:

if one sliding control is added, establishing a combination relationship between the added sliding control and the adjacent sliding control; alternatively, the first and second electrodes may be,

and if the number of the added sliding controls is two and the user sets a combination relation for the two added sliding controls, establishing the combination relation for the two added sliding controls.

10. The interval threshold setting method for the medical device according to claim 8, wherein if a sliding control is deleted, establishing a new combination relationship for the sliding control having a preset combination relationship with the deleted sliding control comprises:

and if one sliding control with the combination relation with the two sliding controls is deleted, establishing the time combination relation of the two sliding controls.

11. The interval threshold setting method for a medical apparatus according to claim 1, wherein the numerical track control is in a shape of a straight bar or a ring.

12. An interval threshold setting method for a medical apparatus, characterized by comprising:

displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises a plurality of numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and the numerical value track controls are associated with a pair of sliding controls with a preset combination relation;

responding to the movement operation of a user on any sliding control on any numerical track control, moving the sliding control to a target position indicated by the movement operation on the numerical track control, and displaying the numerical value of the sliding control at the target position;

and the numerical ranges corresponding to the pair of sliding controls on the same numerical track control are used for forming a state interval.

13. The interval threshold setting method for a medical device according to claim 12, wherein the state intervals on the respective numerical track controls are arranged in tandem, the method further comprising:

if the sliding control of the other numerical track control is connected before or after the moved sliding control, the numerical value corresponding to the connected sliding control changes correspondingly with the change of the numerical value corresponding to the moved sliding control.

14. The interval threshold setting method for a medical device according to claim 12, wherein the interval threshold setting interface includes at least one status flag option, the method further comprising:

and responding to the operation of selecting the state mark for the numerical track control by the user, and establishing the corresponding relation between the state interval formed by the sliding control of the numerical track control and the state represented by the selected state mark.

15. An interval threshold setting apparatus for a medical device, characterized by comprising:

the first setting interface display module is used for displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and at least one pair of sliding controls with a preset combination relation are associated with the numerical value track controls;

the first sliding control moving module responds to the moving operation of a user on at least one sliding control, moves the sliding control to the target position indicated by the moving operation on the numerical track control, and displays the numerical value of the sliding control at the target position;

the numerical value ranges corresponding to the pair of sliding controls are used for forming a state interval.

16. An interval threshold setting apparatus for a medical device, characterized by comprising:

the second setting interface display module is used for displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises a plurality of numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and the numerical value track controls are associated with a pair of sliding controls with a preset combination relation;

the second sliding control moving module is used for responding to the moving operation of a user on any sliding control on any numerical track control, moving the sliding control to the target position indicated by the numerical track control through the moving operation, and displaying the numerical value of the sliding control at the target position;

and the numerical ranges corresponding to the pair of sliding controls on the same numerical track control are used for forming a state interval.

17. A medical device, comprising:

the display is used for displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and the numerical value track controls are associated with at least one pair of sliding controls with a preset combination relation;

the processor responds to the movement operation of a user on at least one sliding control, moves the sliding control to the target position indicated by the movement operation on the numerical track control, and displays the numerical value of the sliding control at the target position;

the numerical value ranges corresponding to the pair of sliding controls are used for forming a state interval.

18. A medical device, comprising:

the display is used for displaying an interval threshold setting interface, wherein the interval threshold setting interface comprises a plurality of numerical value track controls, different positions of the numerical value track controls correspond to numerical values with different sizes, and a pair of sliding controls with a preset combination relation are associated with the numerical value track controls;

the processor responds to the movement operation of a user on any sliding control on any numerical track control, moves the sliding control to the target position indicated by the movement operation on the numerical track control, and displays the numerical value of the sliding control at the target position;

and the numerical ranges corresponding to the pair of sliding controls on the same numerical track control are used for forming a state interval.

19. A readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the method according to any one of claims 1 to 11.

20. A readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the method according to any one of claims 12 to 14.