CN114098678A - Multi-parameter monitor control method and multi-parameter monitor - Google Patents

Abstract

The application discloses a multi-parameter monitor control method and a multi-parameter monitor, wherein the method comprises the following steps: acquiring a trigger event triggered by a key or test paper; acquiring the running state of the monitor when a trigger event occurs; when the running state is the running state of the detection program, judging whether the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state; when not consistent, the trigger event is ignored. When the trigger event is acquired, the current running state of the monitor is analyzed, when the running state is determined to be the running state of the detection program, whether the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state or not is continuously judged, when the target detection program corresponding to the trigger event is inconsistent with the detection program corresponding to the running state, the current trigger event can be represented to be a false touch, the detection program corresponding to the current running state is continuously executed, the trigger event is ignored, therefore, detection interruption caused by the false touch is prevented, and the use of a user is facilitated.

Description

Multi-parameter monitor control method and multi-parameter monitor

Technical Field

The invention relates to the technical field of medical electronic equipment, in particular to a multi-parameter monitor control method and a multi-parameter monitor.

Background

Along with the development of science and technology, various parameter monitors are increasing, and the monitors can help people to monitor the physiological condition of the people and know the health state in time.

The prior art monitors generally detect a plurality of index parameters, such as blood pressure, blood glucose, blood oxygen, and the like. However, due to the reasons of simple structure, different sizes of key design sizes and the like, the operation flow between function selection is overlong, the operation steps are complicated, and the error touch is easy to occur, so that the problems of inaccurate detection result and poor user experience are caused.

Disclosure of Invention

In order to solve the technical problems explained in the background art, a first objective of the present application is to provide a method for preventing a monitor from being touched by mistake between too simple keys, increasing the convenience of testing, and improving the accuracy of detection.

A second objective of the present application is to provide a multi-parameter monitor.

According to the first objective mentioned above, the present application provides a multi-parameter monitor control method, which includes: acquiring a trigger event triggered by a key or test paper; acquiring the running state of the monitor when a trigger event occurs; when the running state is the running state of the detection program, judging whether the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state; and when the target detection program corresponding to the trigger event is inconsistent with the detection program corresponding to the running state, ignoring the trigger event.

Optionally, after ignoring the triggering event, comprising: recording a target detection program corresponding to the trigger event; and determining the response priority of the detection program corresponding to the trigger event according to the occurrence sequence of the trigger event.

Optionally, determining the response priority of the detection program corresponding to the trigger event according to the occurrence sequence of the trigger event includes: adjusting the target detection program corresponding to the trigger event acquired firstly to the highest priority; and when the detection program corresponding to the display state information is finished, prompting to run or running the target detection program corresponding to the trigger event acquired firstly.

Optionally, when the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state, judging whether the completion degree of the detection program corresponding to the running state reaches a preset completion degree; when the completion degree of the detection program does not reach the preset completion degree, finishing the current detection program based on the trigger event; and when the completion degree of the detection program reaches the preset completion degree, ignoring the trigger event and continuously executing the detection program corresponding to the running state.

Optionally, when the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state, obtaining a current detection parameter of the detection program corresponding to the running state; judging whether the detection parameters are in a preset range or not; when the detection parameters exceed the preset detection range, the current detection program is ended based on the trigger event; and when the detection parameters are in the preset detection range, ignoring the trigger event and continuously executing the detection program corresponding to the running state.

Optionally, when the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state, determining the detection type of the detection program corresponding to the running state; when the detection type is an instantaneity detection type, re-entering a detection program corresponding to the running state based on the trigger event; and when the detection type is a procedural detection type, entering a step of acquiring the current detection parameters of the detection program corresponding to the running state.

Optionally, when the running state is a running state other than the detection program; and responding to the trigger event, and entering a target detection program corresponding to the trigger event.

Optionally, before determining whether the display status information and the trigger event match, the method includes: when the running state is the screen turning state; the display screen is illuminated based on the triggering event.

According to a second aspect, an embodiment of the present application provides a multi-parameter monitor, including: a display screen and a plurality of keys; the multi-parameter monitor further comprises a processor, a memory, and executable instructions stored on the memory, the executable instructions being configured to, when executed by the processor, cause the multi-parameter monitor to perform the multi-parameter monitor control method described in any of the above first aspects.

Optionally, the multi-parameter monitor further comprises: the blood glucose meter comprises a processor, at least one of a body temperature detection module, a blood pressure detection module, a blood oxygen detection module, a blood glucose detection module, a cholesterol detection module and a uric acid detection module, wherein the body temperature detection module, the blood pressure detection module, the blood oxygen detection module, the blood glucose detection module, the cholesterol detection module and the uric acid detection module are connected with the processor, each detection module corresponds to one detection key or test paper trigger device, each detection key or test paper trigger device is connected with the processor, and when the detection keys or the test paper trigger devices are triggered, trigger events are output to the processor.

In the application, when the trigger event is acquired, the current running state of the monitor is analyzed, when the running state is determined to be the running state of the detection program, whether the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state or not is continuously judged, when the target detection program corresponding to the trigger event is inconsistent with the detection program corresponding to the running state, the current trigger event can be represented to be a false touch, the detection program corresponding to the current running state is continuously executed, the trigger event is ignored, therefore, detection interruption caused by the false touch is prevented, and the use of a user is facilitated.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic diagram of a multi-parameter monitor control process according to an embodiment of the present application;

FIG. 2 is a schematic diagram of a multi-parameter monitor control process according to another embodiment of the present application;

FIG. 3 is a schematic diagram of a multi-parameter monitor control process according to another embodiment of the present application;

FIG. 4 is a schematic view of a control structure of a multi-parameter monitor according to an embodiment of the present application;

FIG. 5 is a diagram of a multi-parameter monitor control architecture according to another embodiment of the present application.

Detailed Description

In order to more clearly understand the technical features, objects, and effects of the present invention, embodiments of the present invention will now be described with reference to the accompanying drawings, in which the same reference numerals indicate the same or structurally similar but functionally identical elements.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the scope of the present invention is not limited by the specific embodiments disclosed below.

In the prior art, the monitor is used to detect various parameters of physiological status, such as body temperature, blood pressure, blood oxygen and blood sugar, blood ketone, uric acid, etc. The monitor device comprises a testing module for detecting the parameters, a user can select a corresponding key button or use corresponding trigger test paper to enter a corresponding detection program, and meanwhile, the monitor device also comprises a functional module, such as function selection of history detection records, networking binding, setting and the like. Under normal conditions, a user selects a corresponding program key or test paper according to a use scene to enter a corresponding program module, and at a corresponding moment, a display module of the device correspondingly displays corresponding display state information and outputs a detection result to prompt the user. When the user selects the blood pressure, the user can touch the blood pressure detection key by mistake due to factors such as key design and the like, for example, the blood pressure detection key is touched by mistake when the user sets the blood pressure detection key; mistakenly touching the network for binding when the blood pressure test is carried out; and when the blood pressure is detected, a key or test paper for detecting the blood sugar is touched by mistake. The wrong touch can cause man-machine interaction obstacle, increase the complexity of user's use device, detect a series of problems such as data inaccuracy. Based on this, referring to fig. 1, the present application discloses a control method comprising:

s11, acquiring a trigger event triggered by a key or test paper. In this embodiment, the multi-parameter monitor can be triggered by a key or by test paper. For example, the monitor may include a plurality of keys, for example, a plurality of function keys and a plurality of detection keys, and taking the function keys as "user switching key", "memory key" and "distribution network key", and taking the detection keys as "blood pressure detection key", "blood oxygen detection key" and "body temperature detection key" as examples, when the "user switching key" is pressed, a trigger event for switching the current user to another user is represented; when a 'memory key' is pressed, representing a trigger event which can enter and check the historical memory value of the selected test parameter; when a 'distribution network key' is pressed, representing a trigger event which can enter a distribution network interface; when a 'blood pressure detection key' is pressed, representing a trigger event capable of carrying out blood pressure detection; when a 'blood oxygen detection button' is pressed, representing a trigger event capable of carrying out blood oxygen detection; when a body temperature detection button is pressed, representing a trigger event capable of carrying out body temperature detection; when inserted into a blood glucose or uric acid or cholesterol test strip, a trigger event is characterized that allows for the detection of blood glucose or uric acid or cholesterol.

In this embodiment, the trigger event may be obtained by triggering a physical switch and/or by timing the scan of whether a test strip is inserted when the test strip is accessed.

And S12, acquiring the running state of the monitor when the trigger event occurs. In this embodiment, the current operating state may be a state in which the current monitor is operating or a state displayed on an interface, and may include, for example, a certain detection program operating state, a state in which the current monitor is in a main interface, that is, a standby state, or a function setting state, for example, a distribution network state, a user switching state, a state in which a history memory value of a selected test parameter is viewed, and the like. Or the current running state of the monitor is the screen-off state. When the operation state is the detection program operation state, the process proceeds to step S13.

And S13, judging whether the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state. As an exemplary embodiment, when the trigger event represents a trigger event of the detection program, and when the trigger event is acquired, whether the detection program corresponding to the current operation state is consistent with the target detection program corresponding to the trigger event, and if not, the process goes to step S14. When the two match, the flow proceeds to step S15. Determining the detection progress of the detection program corresponding to the test run state,

s14, ignoring the trigger event.

And S15, determining a detection process of the detection program corresponding to the running state, and processing the trigger event based on the trigger event and the detection process. In this embodiment, when the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state, the trigger event may be used as an interrupt condition for interrupting current detection. After the interruption, the target detection program corresponding to the trigger event can be entered. In this embodiment, in order to prevent the trigger event from being caused by the user's false touch or save the test cost, different interrupt conditions may be set for different test programs, so that when the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state, it may be determined whether to ignore the trigger event or to directly execute the target detection program corresponding to the trigger event according to the trigger event based on the trigger event and the detection process. To avoid interference of user usage due to false touches.

When the trigger event is acquired, the current running state of the monitor is analyzed, when the running state is determined to be the running state of the detection program, whether the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state or not is continuously judged, when the target detection program corresponding to the trigger event is inconsistent with the detection program corresponding to the running state, the current trigger event can be represented to be a false touch, the detection program corresponding to the current running state is continuously executed, and the trigger event is ignored, so that detection interruption caused by the false touch is prevented, and convenience is brought to a user.

As an exemplary embodiment, when the user triggers the detection key or inserts the test paper, it may be characterized that the user wants to perform the target detection procedure corresponding to the trigger event triggered by the detection key or the inserted test paper, so as to facilitate the use of the user, after ignoring the trigger event, the target detection procedure corresponding to the trigger event may be recorded. In this embodiment, the trigger event may be a plurality of trigger events that occur sequentially. And determining the response priority of the detection program corresponding to the trigger event according to the occurrence sequence of the trigger event. And performing priority sequencing on the trigger events according to a trigger sequence, and after the trigger program corresponding to the current running state is finished, sequentially executing or sequentially prompting to execute the detection program corresponding to the trigger events based on the priority sequencing. Exemplarily, a target detection program corresponding to a trigger event acquired first is adjusted to be the highest priority; and when the detection program corresponding to the display state information is finished, prompting to run or running the target detection program corresponding to the trigger event acquired firstly.

As an exemplary embodiment, when the target detection program corresponding to the trigger event coincides with the detection program corresponding to the running state, the detection program corresponding to the running state may be interrupted based on the trigger event.

As an exemplary embodiment, after a trigger event triggered by a key or a test strip is obtained, and when it is determined that the running state of the monitor when the trigger event occurs is obtained as a running state of a detection program, a detection process of the detection program corresponding to the running state may be determined, and the trigger event is processed based on the trigger event and the detection process. The detection process may include the completion degree of the detection program, and may include obtaining the detection parameters based on the current detection program. For example, when the trigger event is processed based on the trigger event and the detection process, it may be determined whether the current trigger event needs to ignore or execute its corresponding target detection program based on the detection completion and the obtained detection parameters.

For example, the detecting process may include detecting the completion degree of the program, and when the triggering event is processed based on the triggering event and the detecting process, as shown in fig. 2:

and S21, acquiring the completion degree of the detection program corresponding to the running state.

And S22, judging whether the completion degree of the detection program corresponding to the running state reaches a preset completion degree. In this embodiment, a certain execution process is usually required for executing the detection program, for example, blood oxygen detection, multiple sets of data need to be acquired according to a time sequence, and the multiple sets of data are analyzed to obtain a blood oxygen detection result, for example, blood pressure detection, high-voltage and low-voltage detection need to be performed, and multiple sets of data also need to be acquired according to the time sequence, so that it can be determined whether the detection program corresponding to the current operation state reaches a preset completion degree, for example, the preset completion degree can represent that data acquisition is completed, a data analysis stage is entered, and may also include that some main parameters are completed, or data analysis is completed, and a stage to be output results is entered.

For another example, the test procedure of blood glucose, uric acid and other test strips can be preset to a completion degree based on whether the test strips are used, when the test strips are used, the inserted test strips can be pulled out to serve as a trigger event of the terminal test procedure, when the test strips are pulled out, if the test strips are not used, the terminal can perform the current test, and if the test strips are used, the current test can be continued. In this embodiment, the preset completion degree may be set based on different detection programs. When the preset completion degree is reached, the flow proceeds to step S23. When the preset completion degree is not reached, the flow proceeds to step S24.

S23, ignoring the trigger event, and continuously executing the detection program corresponding to the running state. When the preset completion degree is reached, the data acquisition work or the data analysis work of the current detection program can be represented, consumables required by the test, such as test paper, are used, at this time, the trigger event can be ignored instead of being used as a condition for interrupting the current test, and the current test is continuously completed.

And S24, finishing the current detection program based on the trigger event. In this embodiment, when the preset completion degree is not reached, it may be characterized that the detection program just starts to be executed, and no consumable usage or data collection, data analysis, or other work occurs, so that the current detection program may be ended based on the trigger event. In this embodiment, after the current detection program is ended based on the trigger event, the target detection program corresponding to the trigger event may be directly entered in response to the current trigger event, so as to facilitate the use of the user as much as possible, and achieve the effect of one-touch testing.

For example, the detection process may include a detection parameter of the detection program, and when the trigger event is processed based on the trigger event and the detection process, as shown in fig. 3:

and S31, acquiring the current detection parameters of the detection program corresponding to the running state. As an exemplary embodiment, when the detection program runs, it is necessary to collect data, analyze data, and the like. After a trigger event triggered by a key or test paper is acquired, and when the operation state of the monitor is determined to be the operation state of a detection program when the trigger event occurs, data or a data analysis result acquired by the current detection program can be acquired.

And S32, judging whether the detection parameters are in a preset range. As an exemplary embodiment, generally, when the detection program is running, the acquired data or the analysis result has a certain range of values, for example, when the acquired data has a larger difference from a reasonable data range in a human body in blood pressure detection or blood oxygen detection, the detection parameter is characterized as being within a preset range, and it can be characterized that the current monitor does not test the human body or is not clamped in place. When the detection parameter exceeds the preset detection range, the process proceeds to step S33. When the detection parameter is in the preset detection range, the process proceeds to step S34.

And S33, finishing the current detection program based on the trigger event.

S34, ignoring the trigger event, and continuously executing the detection program corresponding to the running state.

As an exemplary embodiment, taking blood pressure as an example, the high pressure of the human blood pressure is between 90-139mmHg, the low pressure is between 60-89mmHg, the range of the blood pressure parameter is 50-150mmHg as the preset range of the parameter, and whether the detection value is within the interval or not can be judged. And when the detection parameter quantized data exceed the preset range, finishing the current detection program based on the trigger event. Illustratively, when the blood pressure value is beyond 50-150mmHg, the current blood pressure detection is ended. When the completed detection program does not reach the preset range, the detection program can be started by the user by mistake before the detection program is detected to be cancelled by inputting the same trigger signal in a short time. And when the detection parameter quantized data is in the preset range, ignoring the trigger event and continuing the current detection program. When the blood pressure range value is within 50-150mmHg, the signal is ignored, and the blood pressure detection program is continuously executed until the completion.

As an exemplary embodiment, when the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state, before interrupting the detection program corresponding to the running state based on the trigger event, the detection process of the detection program corresponding to the running state may be determined, and whether to interrupt the detection program may be determined based on the trigger event and the detection process. Specifically, refer to the detection process of the detection program corresponding to the determined operation state described in step S21-step S24, or step S31-step S34, and the processing of the trigger event based on the trigger event and the detection process.

As an optional embodiment, before determining the process of the detection program corresponding to the current state, the type of the detection program may be detected, for example, the detection program may include an instantaneous detection type, such as body temperature detection, instantaneous measurement may be performed by infrared, and the required time is short, and the detection program may also include a procedural detection program, such as blood glucose detection, blood pressure detection, and the like, which requires collecting and analyzing multiple sets of data, and further requires a long time for a large detection result. Therefore, when the target detection program corresponding to the trigger event is consistent with the detection program corresponding to the running state, the detection type of the detection program corresponding to the running state is judged; when the detection type is an instantaneity detection type, re-entering a detection program corresponding to the running state based on the trigger event; when the detection type is a procedural detection type, entering a process of determining the detection program corresponding to the current state, for example, entering a step of judging whether the completion degree of the detection program corresponding to the running state reaches a preset completion degree, or entering a step of acquiring the current detection parameter of the detection program corresponding to the running state and judging whether the detection parameter is in a preset range. As an alternative embodiment, different interrupt policies may also be implemented for different types of detection programs.

As an exemplary embodiment, when the trigger event is acquired, the operation state of the monitor may include a function setting state, a main interface state, that is, a standby state, a screen turning state, and the like, besides the detection program operation state. Therefore, when the trigger event is acquired, the current running state may be detected first, and whether the current running state is in the detection program running state, the function setting state, the main interface state, and the screen turning state is determined, and the current running state is matched according to the trigger event, for example, when the trigger event represents a trigger event for running a certain detection program, and if the current state is in the detection program running state, referring to the above embodiment, step S13-step S15 is entered, or step S21-step S24 is entered, or step S31-step S34 is entered. If the current state is in an operating state other than the operating state of the detection program, for example, in a function setting state, a main interface state or a screen-off state, the target detection program corresponding to the trigger event can be directly entered. The one-key access detection function can be realized, and the use of a user is facilitated.

For example, when the operation state is the breath screen state, the display screen may be first lighted up based on the trigger event. As an optional embodiment, after the display screen is lit up, it may be determined whether the current trigger event represents a trigger event for entering the target detection program, and if so, the target detection program corresponding to the trigger event may be directly entered. If not, the screen can be kept in a lighting state. And prompts to trigger the triggering event again.

It should be noted that the above series of tests are only exemplary embodiments, and do not represent the case of only including the above. Any state information detected by the method of the present application is within the scope of the present application.

Fig. 4 is a schematic structural diagram of a multi-parameter monitor according to an embodiment of the present application. The multi-parameter monitor can comprise a display and a plurality of keys, a user inputs a trigger signal to a main control module of the monitor through the keys, and the execution action of the monitor can be displayed to the user through the display, so that man-machine interaction is realized. The multi-parameter monitor may further comprise a processor, a memory, and executable instructions stored on the memory, the executable instructions configured to, when executed by the processor, cause the multi-parameter monitor to perform any of the above-described methods of controlling the multi-parameter monitor. As an exemplary embodiment, a multi-parameter monitor includes: and at least one of a body temperature detection module, a blood pressure detection module, a blood oxygen detection module, a blood sugar detection module, a cholesterol detection module and a uric acid detection module which are connected with the processor. Each test module is connected with a corresponding test key or a test paper trigger device, for example, the body temperature detection module is connected with a corresponding body temperature detection test key, the blood pressure detection module is connected with a corresponding blood pressure detection test key, the blood oxygen detection module is connected with a corresponding blood pressure detection test key, and a user selects one of the trigger test keys to enter a corresponding detection program; the multi-parameter monitor comprises a test paper triggering device, wherein the test paper triggering device is connected with a plurality of detection modules needing test paper triggering, such as a blood glucose detection module, a uric acid detection module and a cholesterol detection module, a user triggers the test paper triggering device by adopting one test paper of blood glucose, uric acid or cholesterol, and after the test triggering is carried out, the corresponding blood glucose, uric acid or cholesterol detection program is entered by identifying the type of the test paper.

For example, the monitor may include a plurality of function keys and a plurality of detection keys, and taking the function setting keys as "user switching key", "memory key" and "distribution network key", and the detection keys as "blood pressure detection key", "blood oxygen detection key" and "body temperature detection key", when the "user switching key" is pressed, a trigger event for switching the current user to another user is represented; when a 'memory key' is pressed, representing a trigger event which can enter and check the historical memory value of the selected test parameter; when a 'distribution network key' is pressed, representing a trigger event which can enter a distribution network interface; when a 'blood pressure detection key' is pressed, representing a trigger event capable of carrying out blood pressure detection; when a 'blood oxygen detection button' is pressed, representing a trigger event capable of carrying out blood oxygen detection; when a body temperature detection button is pressed, representing a trigger event capable of carrying out body temperature detection; when inserted into a blood glucose or uric acid or cholesterol test strip, a trigger event is characterized that allows for the detection of blood glucose or uric acid or cholesterol. The trigger event is transmitted to the processor through an IO port of the processor.

As an exemplary embodiment, the function setting keys are connected with the corresponding function setting modules one by one, for example, the function setting keys corresponding to the function modules of the distribution network, the user switching, the viewing of historical parameters, and the like are convenient for the user to operate, and the state of the monitor can be adjusted through the function setting keys. The size of the function key can be smaller than that of the detection key, so that the error touch of the function module and the test module is avoided when a user operates the function key.

Illustratively, referring to FIG. 5, the multi-parameter monitor may also include memory and a bus, in addition to allowing for the inclusion of hardware required for other services. The memory may include both memory and non-volatile memory (non-volatile memory) and provides execution instructions and data to the processor. Illustratively, the Memory may be a high-speed Random-Access Memory (RAM), and the non-volatile Memory may be at least 1 disk Memory.

Wherein the bus is used to interconnect the processor, the memory, and the network interface. The bus may be an ISA (Industry Standard Architecture) bus, a PCI (Peripheral Component Interconnect) bus, an EISA (Extended Industry Standard Architecture) bus, or the like. The bus may be divided into an address bus, a data bus, a control bus, etc. For ease of illustration, only one double-headed arrow is shown in FIG. 5, but this does not indicate only one bus or one type of bus.

In a possible implementation of the multi-parameter monitor, the processor may first read the corresponding execution instruction from the non-volatile memory to the memory and then operate the corresponding execution instruction, or may first obtain the corresponding execution instruction from another device and then operate the corresponding execution instruction. The processor can implement any one of the above-described methods of controlling a multi-parameter monitor of the present disclosure when executing the execution instructions stored in the memory.

Those skilled in the art will appreciate that the above-described control method for a multi-parameter monitor can be implemented in a processor or by means of a processor. Illustratively, the processor is an integrated circuit chip having the capability to process signals. In the process of executing the control method of the multi-parameter monitor by the processor, the steps of the control method of the multi-parameter monitor can be completed by an integrated logic circuit in the form of hardware or instructions in the form of software in the processor. Further, the Processor may be a general-purpose Processor, such as a Central Processing Unit (CPU), a Network Processor (NP), a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic, discrete hardware components, a microprocessor, or any other conventional Processor.

The embodiments in the present specification are described in a progressive manner, and the same and similar parts among the embodiments are referred to each other, and each embodiment focuses on the differences from the other embodiments. In particular, for the system embodiment, since it is substantially similar to the method embodiment, the description is simple, and for the relevant points, reference may be made to the partial description of the method embodiment.

The above are merely examples of the present invention, and are not intended to limit the present invention. Various modifications and alterations to this invention will become apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (10)

1. A multi-parameter monitor control method is characterized by comprising the following steps:

acquiring a trigger event triggered by a key or test paper;

acquiring the running state of the monitor when the trigger event occurs;

when the running state is a detection program running state,

judging whether a target detection program corresponding to the trigger event is consistent with a detection program corresponding to the running state;

and when the target detection program corresponding to the trigger event is inconsistent with the detection program corresponding to the running state, ignoring the trigger event.

2. The multi-parameter monitor control method of claim 1, further comprising, after ignoring the triggering event:

recording a target detection program corresponding to the trigger event;

and determining the response priority of the detection program corresponding to the trigger event according to the occurrence sequence of the trigger event.

3. The method as claimed in claim 2, wherein said determining the response priority of the detection program corresponding to the triggering event according to the occurrence sequence of the triggering event comprises:

adjusting the target detection program corresponding to the trigger event acquired firstly to the highest priority;

and when the detection program corresponding to the display state information is finished, prompting to run or running a target detection program corresponding to the trigger event acquired firstly.

4. The method as claimed in claim 1, wherein when the operation status is a detection program operation status, the method further comprises:

acquiring the completion degree of a detection program corresponding to the running state;

judging whether the completion degree of the detection program corresponding to the running state reaches a preset completion degree or not;

when the completion degree of the detection program does not reach the preset completion degree, finishing the current detection program based on the trigger event;

and when the completion degree of the detection program reaches a preset completion degree, ignoring the trigger event and continuously executing the detection program corresponding to the running state.

5. The method as claimed in claim 1, wherein when the operation status is a detection program operation status, the method further comprises:

acquiring current detection parameters of a detection program corresponding to the running state;

judging whether the detection parameters are in a preset range or not;

when the detection parameter exceeds the preset detection range, ending the current detection program based on the trigger event;

and when the detection parameters are in the preset detection range, ignoring the trigger event and continuously executing the detection program corresponding to the running state.

6. The method as claimed in claim 5, wherein when said operating status is a detection program operating status, further comprising:

detecting the detection type of a detection program corresponding to the running state;

when the detection type is an instantaneity detection type, re-entering a detection program corresponding to the running state based on the trigger event;

and when the detection type is a procedural detection type, entering a step of acquiring the current detection parameters of the detection program corresponding to the running state.

7. The multi-parameter monitor control method of claim 1,

when the running state is a running state outside the detection program;

and responding to the trigger event, and entering a target detection program corresponding to the trigger event.

8. The method of claim 1, wherein prior to said determining whether said display status information and said triggering event match, comprising:

when the running state is a screen turning state;

illuminating a display screen based on the trigger event.

9. A multi-parameter monitor, comprising: a display screen and a plurality of keys; the multi-parameter monitor further comprises a processor, a memory, and execution instructions stored on the memory, the execution instructions being configured to, when executed by the processor, cause the multi-parameter monitor to perform the multi-parameter monitor control method of any one of claims 1-8.

10. The multi-parameter monitor of claim 9, comprising:

the blood glucose meter comprises a processor, and at least one of a body temperature detection module, a blood pressure detection module, a blood oxygen detection module, a blood glucose detection module, a cholesterol detection module and a uric acid detection module which are connected with the processor, wherein each detection module corresponds to one detection key or test paper trigger device, each detection key or test paper trigger device is connected with the processor, and when the detection key or the test paper trigger device is triggered, a trigger event is output to the processor.

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