CN112997136A - Interface operation method applied to monitoring equipment and monitoring equipment - Google Patents

Abstract

An interface operation method applied to a monitoring device and the monitoring device comprise the following steps: acquiring at least one physiological parameter signal in a first time period by a sensor accessory connected with a patient, and generating parameter data containing at least one physiological parameter according to the acquired at least one physiological parameter signal (S501); displaying parameter data of at least one physiological parameter (S502); receiving the editing operation of a user on the current display interface of the monitoring device (S503); acquiring an editing gesture corresponding to the editing operation (S504); determining the type and direction of interface switching according to the editing gesture (S505), wherein the type of interface switching comprises: a master interface switching type or a slave interface switching type; and according to the type of interface switching, switching the current display interface according to the interface switching direction (S506). By the mode, the monitoring equipment interface can be switched quickly, and the monitoring data checking efficiency of a user is improved.

Description

Interface operation method applied to monitoring equipment and monitoring equipment Technical Field

The invention relates to the technical field of computers, in particular to an interface operation method applied to monitoring equipment and the monitoring equipment.

Background

With the development of computer technology, the application range of computer technology in the medical field is wider and wider. At present, hospitals mainly monitor patients through monitoring equipment, the existing monitoring products monitor all patients by adopting a mode that various operation flows and workflows are crossed together, a unified interactive mode/interactive gesture based on an actual clinical use scene definition product is not available, the working flow is complicated, and medical staff cannot be helped to complete the work of the medical staff quickly, concisely and effectively. In addition, in different clinical application scenarios (such as surgical procedures, short-term monitoring and long-term monitoring), the interface information on the monitoring device has complex searching and interacting modes and interacting steps, and the interaction work of the existing product is complicated according to different monitoring emphasis under different patient states.

Disclosure of Invention

The embodiment of the invention provides an interface operation method applied to a monitoring device and the monitoring device, which can realize the fast interface switching and improve the efficiency of checking patient monitoring data by a user.

In a first aspect, an embodiment of the present invention provides an interface operation method applied to a monitoring device, where the method includes:

acquiring at least one physiological parameter signal in a first time period through a sensor accessory connected with a patient, and generating parameter data containing at least one physiological parameter according to the acquired at least one physiological parameter signal;

displaying parameter data of the at least one physiological parameter;

receiving the editing operation of a user on the current display interface of the monitoring equipment;

acquiring an editing gesture corresponding to the editing operation;

determining the type and the direction of interface switching according to the editing gesture, wherein the type of interface switching comprises the following steps: a master interface switching type or a slave interface switching type;

according to the type of the interface switching, switching the current display interface according to the direction of the interface switching,

wherein, the slave interface comprises a statistical analysis result based on the physiological data displayed by the master interface.

In a second aspect, an embodiment of the present invention provides a monitoring device, including: a data interface, a processor, a memory, said data interface, processor and memory being interconnected, wherein,

the memory for storing a computer program comprising program instructions, the processor configured to invoke the program instructions, perform the steps of:

acquiring at least one physiological parameter signal in a first time period through a sensor accessory connected with a patient, and generating parameter data containing at least one physiological parameter according to the acquired at least one physiological parameter signal;

displaying parameter data of the at least one physiological parameter;

receiving the editing operation of a user on the current display interface of the monitoring equipment;

acquiring an editing gesture corresponding to the editing operation;

determining the type and the direction of interface switching according to the editing gesture, wherein the type of interface switching comprises the following steps: a master interface switching type or a slave interface switching type;

and switching the current display interface according to the type of the interface switching and the direction of the interface switching, wherein the slave interface comprises a statistical analysis result of the physiological data displayed on the basis of the master interface.

In a third aspect, an embodiment of the present invention provides another interface operation method applied to a monitoring device, where the method includes:

acquiring at least one physiological parameter signal in a first time period through a sensor accessory connected with a patient, and generating a real-time waveform and/or a real-time numerical value containing at least one physiological parameter according to the acquired at least one physiological parameter signal;

displaying the real-time waveform and/or real-time numerical value of the at least one physiological parameter on a display interface;

receiving the editing operation of a user on the current display interface of the monitoring equipment;

acquiring an editing gesture corresponding to the editing operation;

determining a switching direction according to the editing gesture;

and displaying a slave interface expansion on the display interface along the switching direction, wherein the slave interface comprises a statistical analysis result based on the real-time waveform and/or the real-time numerical value.

In a fourth aspect, an embodiment of the present invention provides another monitoring device, where the monitoring device includes:

a parameter measurement circuit electrically connected to a sensor accessory disposed on a patient's body for obtaining at least one physiological parameter signal;

a processor and a memory;

the memory is used for storing computer programs, and the processor is used for implementing the following steps when executing the computer programs stored in the memory:

generating a real-time waveform and/or a real-time numerical value containing at least one physiological parameter according to the obtained at least one physiological parameter signal;

displaying the real-time waveform and/or real-time numerical value of the at least one physiological parameter on a display interface;

receiving the editing operation of a user on the current display interface of the monitoring equipment;

acquiring an editing gesture corresponding to the editing operation;

determining a switching direction according to the editing gesture;

and displaying a slave interface expansion on the display interface along the switching direction, wherein the slave interface comprises a statistical analysis result based on the real-time waveform and/or the real-time numerical value.

In an embodiment of the present invention, the monitoring device obtains at least one physiological parameter signal during a first time period by a sensor accessory connected to the patient, generates parameter data including at least one physiological parameter according to the obtained at least one physiological parameter signal, and displays the parameter data of the at least one physiological parameter. The monitoring device can receive the editing operation of a user on the current display interface of the monitoring device, obtain the editing gesture corresponding to the editing operation, determine the type and the direction of interface switching according to the editing gesture, and switch the current display interface according to the type of interface switching and the direction of interface switching, so that the interface of the monitoring device is quickly switched, and the monitoring data checking efficiency of the user is improved.

Drawings

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

FIG. 1 is a schematic diagram of a large digital interface provided by an embodiment of the present invention;

FIG. 2 is a schematic diagram of a waveform interface provided by an embodiment of the present invention;

FIG. 3 is a schematic diagram of a state trend interface provided by an embodiment of the present invention;

FIG. 4 is a schematic diagram of another state trend interface provided by embodiments of the present invention;

FIG. 5 is a schematic flowchart of an interface operation method according to an embodiment of the present invention;

FIG. 6 is a schematic flow chart diagram illustrating another interface operation method according to an embodiment of the present invention;

FIG. 7 is a schematic diagram of a scoring interface provided by embodiments of the present invention;

FIG. 8 is a diagram illustrating a scoring details interface provided by an embodiment of the present invention;

FIG. 9 is a schematic diagram of another scoring detail interface provided by embodiments of the present invention;

FIG. 10 is a schematic structural diagram of a monitoring device according to an embodiment of the present invention;

FIG. 11 is a monitor networking system for use in a hospital, according to an embodiment of the present invention;

FIG. 12 is a system block diagram of a multi-parameter monitor or module assembly according to an embodiment of the present invention;

FIG. 13A is an interface diagram of waveforms and/or values of a physiological parameter at different times according to an embodiment of the present invention;

FIG. 13B is an interface graph of waveforms and/or values of another physiological parameter at different times according to embodiments of the present invention;

FIG. 13C is an interface diagram of waveforms and/or values of a further physiological parameter at different times according to an embodiment of the present invention;

FIG. 13D is an interface diagram of a scoring history provided by an embodiment of the present invention;

FIG. 13E is an interface diagram showing a state trend, according to an embodiment of the present invention;

fig. 14 is a schematic flowchart of another interface operation method according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Usually, when a patient in a hospital is located in the hospital, a plurality of physiological parameters of the patient need to be paid attention at any time through a monitor. As shown in fig. 11, fig. 11 is a monitor networking system for use in a hospital according to an embodiment of the present invention, and the system can be used to store data of a monitor as a whole, manage patient information and care information in a centralized manner, and store the patient information and the care information in an associated manner, so as to facilitate storage of historical data and associated alarm. In the system shown in fig. 11, a bedside monitor 212 may be provided for each patient bed, and the bedside monitor 212 may be a multi-parameter monitor or a modular component. In addition, each bedside monitor 212 can also be paired with a portable monitoring device 213 for transmission, the portable monitoring device 213 provides a simple and portable parameter processing module, the portable monitoring device can be worn on the body of a patient to perform mobile monitoring on the patient, and physiological data generated by the mobile monitoring can be transmitted to the bedside monitor 212 for display after the portable monitoring device 213 is in wired or wireless communication with the bedside monitor 212, or transmitted to the central station 211 for a doctor or a nurse to view through the bedside monitor 212, or transmitted to the data server 215 for storage through the bedside monitor 212. In addition, the portable monitoring device 213 can also directly transmit the physiological data generated by the mobile monitoring to the central station 211 through the wireless network node 214 arranged in the hospital for storage and display, or transmit the physiological data generated by the mobile monitoring to the data server 215 through the wireless network node 214 arranged in the hospital for storage. It can be seen that the data corresponding to the physiological parameters displayed on the bedside monitor 212 may originate from a sensor accessory directly connected to the monitor 212, or from the portable monitoring device 213, or from the data server 215. In addition, the printing device 216 may also obtain corresponding instruction signals from the bedside monitor 212 or the central station 211 through the network shown in fig. 11.

FIG. 12 is a system diagram of a multi-parameter monitor or module assembly according to an embodiment of the present invention, as shown in FIG. 12. The multi-parameter monitor or module assembly includes at least a parameter measurement circuit 912. The parameter measuring circuit 912 at least comprises a parameter measuring circuit corresponding to a physiological parameter, the parameter measuring circuit 912 at least comprises at least one parameter measuring circuit of an electrocardiosignal parameter measuring circuit, a respiration parameter measuring circuit, a body temperature parameter measuring circuit, a blood oxygen parameter measuring circuit, a non-invasive blood pressure parameter measuring circuit, an invasive blood pressure parameter measuring circuit and the like, and each parameter measuring circuit 912 is respectively connected with an externally inserted sensor accessory 911 through a corresponding sensor interface. The sensor accessory 911 includes a detection accessory corresponding to detection of physiological parameters such as electrocardiographic respiration, blood oxygen, blood pressure, body temperature and the like. The parameter measurement circuit 912 is mainly used for connecting the sensor accessory 911 to obtain the acquired physiological parameter signal, and may include at least two measurement circuits of physiological parameters, and the parameter measurement circuit 912 may be, but is not limited to, a physiological parameter measurement circuit (module), a human physiological parameter measurement circuit (module) or a sensor for acquiring human physiological parameters, etc. Specifically, the parameter measurement circuit 912 obtains physiological sampling signals of the patient from the external physiological parameter sensor accessory through the expansion interface, and obtains physiological data after processing the physiological sampling signals for alarming and displaying. The expansion interface can also be used for outputting a control signal which is output by the main control circuit and is about how to acquire the physiological parameters to an external physiological parameter monitoring accessory through a corresponding interface, so that the monitoring control of the physiological parameters of the patient is realized.

The multi-parameter monitor or module assembly may further include a main control circuit 913, where the main control circuit 913 needs to include at least one processor and at least one memory, and of course, the main control circuit 913 may further include at least one of a power management module, a power IP module, an interface conversion circuit, and the like. The power management module is used for controlling the on and off of the whole machine, the power-on time sequence of each power domain in the board card, the charging and discharging of the battery and the like. The power supply IP module is used for associating a schematic diagram of a power supply circuit unit which is frequently called repeatedly with a PCB layout and solidifying the schematic diagram into a single power supply module, namely converting an input voltage into an output voltage through a preset circuit, wherein the input voltage is different from the output voltage. For example, a voltage of 15V is converted into 1.8V, 3.3V, 3.8V, or the like. It is understood that the power supply IP block may be single-pass or multi-pass. When the power supply IP block is single-pass, the power supply IP block may convert an input voltage into an output voltage. When the power IP module is the multichannel, the power IP module can be a plurality of output voltage with an input voltage conversion, and a plurality of output voltage's magnitude of voltage can be the same, also can not be the same to can satisfy a plurality of electronic component's different voltage demands simultaneously, and the module is few to the external interface, and the work is black box and external hardware system decoupling zero in the system, has improved whole electrical power generating system's reliability. The interface conversion circuit is used for converting signals output by the minimum system main control module (i.e. at least one processor and at least one memory in the main control circuit) into input standard signals required to be received by actual external equipment, for example, supporting an external VGA display function, converting RGB digital signals output by the main control CPU into VGA analog signals, supporting an external network function, and converting RMII signals into standard network differential signals.

In addition, the multi-parameter monitor or module assembly may also include one or more of a local display 914, an alarm circuit 916, an input interface circuit 917, and an external communication and power interface 915. The main control circuit is used for coordinating and controlling each board card, each circuit and each device in the multi-parameter monitor or the module assembly. In this embodiment, the main control circuit is used to control data interaction between the parameter measurement circuit 912 and the communication interface circuit, and control signal transmission, and transmit physiological data to the display 914 for display, or receive a user control command input from a touch screen or a physical input interface circuit such as a keyboard and a key, or of course, output a control signal on how to acquire physiological parameters. The alarm circuit 916 may be an audible and visual alarm circuit. The main control circuit completes the calculation of the physiological parameters, and the calculation result and waveform of the parameters can be sent to a host (such as a host with a display, a PC, a central station, etc.) through the external communication and power interface 915, and the external communication and power interface 915 may be one or a combination of a local area network interface composed of Ethernet (Ethernet), a Token Ring (Token Ring), a Token Bus (Token Bus), and a backbone Fiber Distributed Data Interface (FDDI) as these three networks, one or a combination of wireless interfaces such as infrared, bluetooth, wifi, WMTS communication, etc., or may also be one or a combination of wired data connection interfaces such as RS232, USB, etc. The external communication and power interface 915 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 multi-parameter monitor or the module component sends data to the mobile phone supporting Bluetooth communication through the Bluetooth interface to realize remote transmission of the data.

The multi-parameter monitoring module component can be arranged outside the monitor shell and used as an independent external parameter monitoring module, a plug-in monitor can be formed by a host (comprising a main control board) inserted into the monitor and used as a part of the monitor, or the multi-parameter monitoring module component can be connected with the host (comprising the main control board) of the monitor through a cable, and the external parameter monitoring module is used as an external accessory of the monitor. Of course, the parameter processing can also be arranged in the shell and integrated with the main control module, or physically separated and arranged in the shell to form the integrated monitor.

Some embodiments of the invention are described in detail below with reference to the accompanying drawings. The embodiments described below and the features of the embodiments can be combined with each other without conflict.

The scheme provides an interface operation method on a monitoring device (the monitor 212 or the central station 211), which is mainly applied to the monitoring device in the medical field.

At least one physiological parameter signal is obtained by a sensor accessory connected with a patient in a first time period, and parameter data containing at least one physiological parameter is generated according to the obtained at least one physiological parameter signal. And displaying the parameter data of the at least one physiological parameter to obtain a current display interface of the monitoring equipment. The monitoring device obtains an editing gesture corresponding to the editing operation by receiving the editing operation of a user on a current display interface of the monitoring device, and determines the type and the direction of interface switching according to the editing gesture, wherein the type of interface switching comprises the following steps: and the monitoring equipment switches the current display interface according to the interface switching type and the interface switching direction, so that the monitoring equipment interface is switched rapidly and effectively, and the monitoring data viewing efficiency is improved. While the recognition of an editing gesture obtained on the display interface relies on the acquisition of a data source through the input interface circuitry 917 or a touch screen superimposed within the display 914 for processing by the processor.

In one embodiment, the interface of the monitoring device may include a master interface and a slave interface, the master interface may include a large number interface and/or a waveform interface; the slave interface is subordinate to the master interface, and the slave interface can comprise any one or more of a state trend interface, a scoring interface and a scoring detail interface. It should be noted that the large digital interface displays relevant data of patients, the waveform interface displays waveform data of patient states, the state trend interface displays information such as specific states or trends of various patients, the scoring interface displays scores of patient states, and the scoring detail interface displays detailed scoring information such as historical scores of patients. For the slave interface structure based on the scoring interface, the scoring detail interface, etc., reference is made to fig. 13A and its related description, which will be explained in detail below. In this embodiment, the slave interface has more statistical analysis details than the master interface. The master interface primarily presents real-time waveforms and/or real-time values, while the slave interface includes statistical analysis results regarding real-time waveforms and/or real-time values at different times, that is, in one embodiment, the slave interface includes statistical analysis results based on the physiological data displayed by the master interface.

In an embodiment, the editing gesture of the editing operation acquired by the monitoring device may include a touch point and a touch direction, and when the monitoring device determines the type and the direction of interface switching according to the editing gesture, the monitoring device may acquire the number of touch points included in the editing gesture. The monitoring device can determine the type of interface switching by detecting the number of the touch points, and if the number of the touch points is greater than a preset threshold, the monitoring device can determine that the type of interface switching is a main interface switching type and determine the touch direction as a main interface switching direction. If the number of the touch points is less than or equal to the preset threshold, the monitoring device may determine that the type of the interface switching is a slave interface switching type, and determine the touch direction as a slave interface switching direction. The editing operation acquired by the monitoring device may be a click operation or other operations such as a sliding operation. The preset threshold of the number of the touch points in the embodiment of the present invention may be any value, and the embodiment of the present invention is not limited. The embodiment of the invention does not limit the relation between the touch point and the touch direction included in the editing gesture of the editing operation and the interface switching type and direction, and only needs to determine the interface switching type and direction according to the touch point and/or the touch direction.

In an embodiment, if the monitoring device detects that the type of interface switching is a main interface switching type, it may determine that the current display interface is the corresponding first main interface, obtain a second main interface according to the main interface switching direction, and switch the current display interface to the second main interface.

Specifically, the description may be given by taking fig. 1 and fig. 2 as an example, where fig. 1 is a schematic diagram of a large digital interface according to an embodiment of the present invention, the large digital interface shown in fig. 1 includes a sliding operation 11, the number of touch points included in a sliding gesture corresponding to the sliding operation 11 of the large digital interface is 2, and the touch direction is rightward in the interface horizontal direction. Fig. 2 is a schematic diagram of a waveform interface according to an embodiment of the present invention, where the waveform interface shown in fig. 2 includes a first slide operation 21, a second slide operation 22, a first shortcut control 23, and a second shortcut control 24. It should be noted that the large number interface shown in fig. 1 and the waveform interface shown in fig. 2 belong to different types of main interfaces.

For example, assuming that the current display interface of the monitoring device is a large digital interface as shown in fig. 1, assuming that the monitoring device receives an editing operation of a user on the large digital interface, and the editing operation is a sliding operation 11, if the monitoring device obtains that the number of touch points included in a sliding gesture corresponding to the sliding operation 11 is 2, the touch direction is the interface horizontal right direction, and assuming that a preset threshold of the number of touch points is 1, since 2>1, the monitoring device may determine that the type of interface switching is a main interface switching type, determine the acquired horizontal right touch direction as the main interface switching direction, and determine that the large digital interface is the first main interface. The monitoring device may obtain that the second main interface is the waveform interface as shown in fig. 2 according to the direction of the horizontal right main interface switching obtained on the large digital interface. Therefore, when the monitoring device acquires a sliding operation with 2 touch points and a horizontal touch direction, on the large digital interface shown in fig. 1, the monitoring device can switch the large digital interface to the waveform interface shown in fig. 2.

For another example, assuming that the current display interface of the monitoring device is the waveform interface as shown in fig. 2, assuming that the monitoring device receives the editing operation of the waveform interface by the user as the first sliding operation 21, the touch points corresponding to the first sliding operation 21 are 2, the sliding direction is horizontal to the left, and the preset threshold of the number of the touch points is 1, since 2>1, it may be determined that the interface switching type is the primary interface switching type, and it may be determined that the current waveform interface is the first primary interface, and the second primary interface is the large number interface. When receiving the first sliding operation 21 with 2 touch points and a horizontal and left sliding direction as shown in fig. 2, the monitoring device may switch the currently displayed waveform interface shown in fig. 2 to the large digital interface shown in fig. 1.

In one embodiment, if the type of the interface switch acquired by the monitoring device is the slave interface switch type, the monitoring device may acquire the target slave interface according to the acquired slave interface switch direction. Specifically, fig. 2 and fig. 3 are taken as examples for explanation, wherein fig. 3 is a schematic diagram of a state trend interface according to an embodiment of the present invention. The state trend interface as shown in fig. 3 includes a first slide operation 31, a second slide operation 32, a first shortcut control 33, and a second shortcut control 34. The state trend interface shown in fig. 3 is a slave interface, and is subordinate to the waveform interface shown in fig. 2.

For example, assuming that the current display interface of the monitoring device is the waveform interface shown in fig. 2, assuming that the monitoring device receives that the editing operation of the waveform interface by the user is the second sliding operation 22, the touch points corresponding to the second sliding operation 22 are 1, the sliding direction is horizontal to the right, and assuming that the preset threshold of the number of the touch points is 1, the monitoring device may determine that the interface switching type is the slave interface switching type, and may determine that the target slave interface is the state trend interface shown in fig. 3 according to the sliding direction of the horizontal to the right. When the monitoring device receives the second sliding operation 22 with 1 touch point and the sliding direction being horizontal and rightward as shown in fig. 2, the monitoring device may switch the currently displayed waveform interface as shown in fig. 2 to the state trend interface as shown in fig. 3, so that the user can view the state trend information of the patient.

For another example, assuming that the current display interface of the monitoring device is the state trend interface shown in fig. 3, if the monitoring device receives that the editing operation of the user on the state trend interface is the first sliding operation 31, and the number of the touch points of the first sliding operation 31 is 1, and the sliding direction is horizontal to the left, it may be determined that the interface switching type is the slave interface switching type, and it is determined that the target slave interface is the waveform interface shown in fig. 2 according to the number of the touch points of the first sliding operation 31 and the sliding direction. Therefore, when the monitoring device receives the first sliding operation 31 with 1 touch point and a horizontal left sliding direction on the state trend interface shown in fig. 3, the currently displayed state trend interface can be switched to the waveform interface shown in fig. 2.

In an embodiment, the description may be specifically illustrated by taking fig. 3 and fig. 4 as an example, where fig. 4 is a schematic diagram of another state trend interface provided by the embodiment of the present invention. The state trend interface shown in FIG. 4 includes a slide operation 41, a first shortcut control 42, and a second shortcut control 43. It should be noted that the state trend interface shown in fig. 4 is a slave interface, and the slave interface is associated with the state trend interface shown in fig. 3.

For example, assuming that the current display interface of the monitoring device is the state trend interface shown in fig. 3, if the monitoring device receives that the editing operation of the user on the state trend interface shown in fig. 3 is the second sliding operation 32, and the touch points of the second sliding operation 32 are 1, and the sliding direction is horizontal to the right, it may be determined that the interface switching type is the slave interface switching type, and it is determined that the target slave interface is the state trend interface shown in fig. 4 according to the touch direction of the second sliding operation 32 and the number of the touch points. Therefore, when the monitoring device receives the second sliding operation 32 with 1 touch point and a horizontal sliding direction on the state trend interface shown in fig. 3, the currently displayed state trend interface can be switched to the state trend interface shown in fig. 4.

For another example, assuming that the current display interface of the monitoring device is the state trend interface shown in fig. 4, if the monitoring device receives that the editing operation of the user on the state trend interface is the sliding operation 41, and the number of the touch points acquiring the sliding operation 41 is 1, and the sliding direction is horizontal to the left, it may be determined that the interface switching type is the slave interface switching type, and the slave interface is the state trend interface shown in fig. 3 according to the acquired number of the touch points and the acquired touch direction. Therefore, when the monitoring device receives the sliding operation 41 with 1 touch point and the sliding direction being horizontal and left on the state trend interface shown in fig. 4, the currently displayed state trend interface can be switched to the state trend interface shown in fig. 3.

The interface operation method provided by the embodiment of the invention needs to be realized by the monitoring device, and the interface operation method applied to the monitoring device is described in detail below with reference to the accompanying drawings.

Referring to fig. 5 in detail, fig. 5 is a schematic flowchart of an interface operation method according to an embodiment of the present invention, where the method can be executed by a monitoring device, and the monitoring device can be a monitoring device such as a monitor. Specifically, the method of the embodiment of the present invention includes the following steps.

S501: at least one physiological parameter signal is obtained by a sensor accessory connected with a patient in a first time period, and parameter data containing at least one physiological parameter is generated according to the obtained at least one physiological parameter signal.

In an embodiment of the invention, the monitoring device may obtain at least one physiological parameter signal during a first time period by a sensor accessory connected to the patient, and generate parameter data including at least one physiological parameter according to the obtained at least one physiological parameter signal.

S502: displaying parameter data of the at least one physiological parameter.

In an embodiment of the present invention, after the monitoring device generates the parameter data including at least one physiological parameter, the parameter data of the at least one physiological parameter may be displayed.

S503: and receiving the editing operation of the user on the current display interface of the monitoring device.

In the embodiment of the invention, the monitoring device can receive the editing operation of the user on the current display interface of the monitoring device. Wherein the editing operation may include, but is not limited to, a swipe operation or a click operation. In one embodiment, the current display interface of the monitoring device may include a master interface or a slave interface, the master interface may include a large number interface and/or a waveform interface; the slave interface is subordinate to the master interface, and the slave interface can comprise any one or more of a state trend interface, a scoring detail interface and a scoring history interface. For example, the monitoring device may receive a swipe operation of the current display interface.

S504: and acquiring an editing gesture corresponding to the editing operation.

In the embodiment of the invention, the monitoring device can acquire the editing gesture corresponding to the editing operation according to the received editing operation of the user on the current display interface of the monitoring device. The editing gesture comprises a touch point and/or a touch direction.

S505: and determining the type and direction of interface switching according to the editing gesture.

In the embodiment of the present invention, the monitoring device may determine the type and direction of interface switching according to the obtained editing gesture, where the type of interface switching includes: a master interface switch type or a slave interface switch type. It should be noted that the master interface switching type is switching between master interfaces, and the slave interface switching is switching between slave interfaces, or switching between master interfaces and slave interfaces. The slave interface herein may include a statistical analysis result based on the physiological data displayed by the master interface, and the statistical analysis result is presented as any one or more of a state trend interface, a scoring detail interface, and a scoring history interface.

In an embodiment, the monitoring device may obtain, according to the obtained editing gesture, the number of touch points included in the editing gesture, and if the number of touch points is greater than a preset threshold, may determine that the type of interface switching is a primary interface switching type, and determine a touch direction included in the editing gesture as a primary interface switching direction. If the number of the touch points is smaller than or equal to the preset threshold, the type of interface switching can be determined to be a slave interface switching type, and the touch direction is determined to be a slave interface switching direction.

Specifically, it can be described by taking fig. 1 and fig. 2 as an example, for example, assuming that a current display interface of the monitoring device is a large digital interface as shown in fig. 1, if the monitoring device receives an editing operation on the large digital interface as a sliding operation 11 as shown in fig. 1, the monitoring device may acquire that the number of touch points included in a sliding gesture corresponding to the sliding operation 11 is 2, and the touch direction is a horizontal right direction. Assuming that the preset threshold of the number of the touch points preset by the monitoring device is 1, the number of the touch points is greater than the preset threshold, that is, 2>1, the monitoring device can determine that the type of interface switching is a main interface switching type, and determine the horizontal right touch direction as a main interface switching direction.

For another example, assuming that the current display interface of the monitoring device is a waveform interface as shown in fig. 2, if the monitoring device receives that the editing operation on the waveform interface is the second sliding operation 22 as shown in fig. 2, the monitoring device may acquire that the number of touch points included in the sliding gesture corresponding to the second sliding operation 22 is 1, and the touch direction is a horizontal right direction. Assuming that the preset threshold of the number of the touch points preset by the monitoring device is 1, the number of the touch points is equal to the preset threshold, and the monitoring device may determine that the type of the interface switching is the slave interface switching type, and determine the horizontal right touch direction as the slave interface switching direction.

S506: and switching the current display interface according to the interface switching direction according to the type of the interface switching.

According to the embodiment of the invention, the monitoring equipment can switch the current display interface according to the type of the interface switching and the direction of the interface switching, wherein the slave interface comprises a statistical analysis result of the physiological data displayed based on the main interface.

In an embodiment, if the monitoring device determines that the interface switching type is the primary interface switching type, the monitoring device may determine a first primary interface corresponding to the current display interface, obtain a second primary interface according to the primary interface switching direction, and switch the current display interface to the second primary interface. Specifically, it can be described by taking fig. 1 and fig. 2 as an example, assuming that a current display interface of the monitoring device is a large digital interface, if the monitoring device determines that the type of interface switching is a primary interface switching type according to a touch point and a touch direction of a sliding operation 11 received on the large digital interface, the monitoring device may determine that the large digital interface is a first primary interface, obtain that a second primary interface is a waveform interface as shown in fig. 2 according to the horizontal rightward touch direction, and switch the large digital interface of the current display interface to the waveform interface as shown in fig. 2.

In one embodiment, if the monitoring device determines that the type of interface switching is the slave interface switching type, the monitoring device may acquire the target slave interface according to the slave interface switching direction and switch the currently displayed interface to the target slave interface. Specifically, it can be explained by taking fig. 2 and fig. 3 as an example, assuming that the current display interface of the monitoring device is the waveform interface as shown in fig. 2, if the monitoring device receives that the editing operation of the waveform interface by the user is the second sliding operation 22, and the touch points corresponding to the second sliding operation 22 are 1, and the sliding direction is horizontal to the right. Assuming that the preset threshold of the number of the touch points is 1, the monitoring device may determine that the interface switching type is a slave interface switching type, and may determine that the state trend interface shown in fig. 3 is a target slave interface according to the horizontal rightward sliding direction. When receiving the second sliding operation 22 with 1 touch point and the sliding direction being horizontal and rightward as shown in fig. 2, the monitoring device may switch the currently displayed waveform interface as shown in fig. 2 to the state trend interface as shown in fig. 3.

In one embodiment, when the monitoring device switches the current display interface according to the switching direction and the type of the interface switching, any one or more of a state trend interface, a scoring detail interface and a scoring history interface may be deployed from the edge of the main interface according to the editing gesture; or, according to the editing gesture, unfolding or gradually unfolding the scoring interface from the edge of the main interface along a first direction; or, according to the editing gesture, unfolding or gradually unfolding a scoring detail interface along a second direction from the scoring interface; or expanding or gradually expanding a state trend interface from the grading interface along a third direction according to the editing gesture; or, according to the editing gesture, expanding or gradually expanding a grading history interface from the grading detail interface along a second direction; or, along with the sliding of the editing gesture on the display interface, sequentially unfolding the short-time trend change chart and the long-time trend change chart in the state trend interface along the third direction. In certain embodiments, the third direction and the second direction are different. The specific embodiments and examples are as described above and will not be described herein again.

According to the embodiment of the invention, the monitoring device obtains at least one physiological parameter signal in a first time period through a sensor accessory connected with a patient, generates parameter data containing at least one physiological parameter according to the obtained at least one physiological parameter signal, and displays the parameter data of the at least one physiological parameter. The monitoring device can receive the editing operation of a user on the current display interface of the monitoring device, obtain the editing gesture corresponding to the editing operation, and determine the type and the direction of interface switching according to the editing gesture, so that the current display interface is switched according to the type of interface switching and the direction of interface switching. By the mode, the method and the system realize the quick switching operation of the monitoring equipment interface, and improve the monitoring data checking efficiency of the user.

Referring to fig. 6 specifically, fig. 6 is a schematic flowchart of another interface operation method provided in the embodiment of the present invention, and the difference between the method and the embodiment of the method of fig. 5 is that the method of the embodiment of the present invention may obtain a control instruction by receiving a click operation of a shortcut control on a user interface by a user, so as to control a currently displayed interface to be switched to an interface corresponding to the shortcut control. Specifically, the method of the embodiment of the present invention includes the following steps.

S601: and receiving the editing operation of the user on the current display interface of the monitoring device.

In the embodiment of the invention, the monitoring device can receive the editing operation of the user on the current display interface of the monitoring device. The editing operation may be, but is not limited to, a sliding operation or a clicking operation.

S602: and if the editing operation is the clicking operation of the shortcut control by the user, acquiring an interface switching instruction.

In the embodiment of the invention, if the monitoring device determines that the received editing operation is the click operation of the user on the shortcut control on the current display interface, the interface switching instruction can be obtained. Specifically, the description may be given by taking fig. 2 as an example, for example, if the monitoring device obtains a click operation on the first shortcut control 23 on the current display interface, that is, the waveform interface, shown in fig. 2, the monitoring device may obtain an interface switching instruction, where a switching interface corresponding to the first shortcut control 23 is a state trend interface shown in fig. 3. For another example, assuming that the monitoring device obtains a click operation on the second shortcut control 24 on the current display interface, i.e., the waveform interface, as shown in fig. 2, the monitoring device may obtain an interface switching instruction, where a switching interface corresponding to the second shortcut control 24 is the scoring interface as shown in fig. 7. Fig. 7 is a schematic diagram of a scoring interface according to an embodiment of the present invention, and as shown in fig. 7, the scoring interface includes a slide operation 71 and a shortcut control 72.

S603: and responding to the interface switching instruction, and switching the current display interface to the interface corresponding to the shortcut control.

In the embodiment of the invention, if the monitoring device acquires the interface switching instruction, the monitoring device can respond to the interface switching instruction and switch the current display interface to the interface corresponding to the shortcut control. In an embodiment, specifically, as illustrated in fig. 2 and fig. 3 as an example, it is assumed that the monitoring device acquires a click operation on the first shortcut control 23 on the current display interface, that is, the waveform interface, as shown in fig. 2, and the monitoring device can acquire an interface switching instruction, where a switching interface corresponding to the first shortcut control 23 is a state trend interface as shown in fig. 3, and thus the monitoring device can respond to the interface switching instruction and switch the currently displayed waveform interface as shown in fig. 2 to the state trend interface as shown in fig. 3 corresponding to the first shortcut control 23.

In another embodiment, specifically, by taking fig. 2 and fig. 7 as an example, assuming that the monitoring device obtains a click operation on the second shortcut control 24 on the current display interface, that is, the waveform interface, shown in fig. 2, the monitoring device may obtain an interface switching instruction, where a switching interface corresponding to the second shortcut control 24 is the scoring interface shown in fig. 7, and therefore, the monitoring device may respond to the interface switching instruction to switch the current waveform interface shown in fig. 2 to the scoring interface shown in fig. 7.

In one embodiment, the monitoring device may receive an editing operation of the scoring interface by a user after switching the currently displayed interface to the scoring interface, wherein the editing operation includes, but is not limited to, a sliding operation or a clicking operation. The embodiment of the invention does not limit the interface switching type and direction corresponding to the touch point and the touch direction corresponding to the editing operation, and only needs to determine the interface switching type and direction according to the touch point and/or the touch direction.

Specifically, the scoring detail interface may be described by taking fig. 7 and fig. 8 as an example, where fig. 8 is a schematic diagram of a scoring detail interface provided in an embodiment of the present invention, and the scoring detail interface shown in fig. 8 includes a first sliding operation 81, a second sliding operation 82, and a shortcut control 83. For example, assuming that the currently displayed interface of the monitoring device is the scoring interface shown in fig. 7, if the monitoring device receives a first sliding operation 81 shown in fig. 7 from a user, the monitoring device may determine that the touch points of the first sliding operation 81 are 1 and the touch direction is vertically upward. Assuming that the preset threshold of the number of the touch points is 1, the monitoring device may determine that the type of the interface switching is slave interface switching, and determine that the target slave interface is the scoring detail interface shown in fig. 8 according to the touch direction, so that the monitoring device may switch the currently displayed scoring interface shown in fig. 7 to the scoring detail interface shown in fig. 8. For another example, if the monitoring device receives a user click operation on the shortcut control 72 shown in fig. 7, the currently displayed scoring interface shown in fig. 7 may be switched to the scoring detail interface shown in fig. 8.

In an embodiment, the descriptions are given by taking fig. 7, fig. 8, and fig. 9 as examples, where fig. 9 is a schematic diagram of another scoring detail interface provided by an embodiment of the present invention, and the scoring detail interface shown in fig. 9 includes a sliding operation 91 and a shortcut control 92. For example, assuming that the currently displayed interface of the monitoring device is the scoring detail interface shown in fig. 8, if the monitoring device receives a user's second sliding operation 82 shown in fig. 8, the monitoring device may determine that the touch points of the second sliding operation 82 are 1 and the touch direction is vertical downward. Assuming that the preset threshold of the number of the touch points is 1, the monitoring device may determine that the type of the interface switching is the slave interface switching, and determine that the target slave interface is the scoring interface shown in fig. 7 according to the touch direction, so that the monitoring device may switch the currently displayed scoring detail interface shown in fig. 8 to the scoring interface shown in fig. 7.

For another example, assuming that the monitoring device receives a user's first sliding operation 81 as shown in fig. 8, the monitoring device may determine that the touch points of the first sliding operation 81 are 1 and the touch direction is horizontal to the right. Assuming that the preset threshold of the number of the touch points is 1, then 2>1, the monitoring device may determine that the type of the interface switching is switching from the interface, and determine that the target slave interface is another scoring detail interface as shown in fig. 9 according to the touch direction, and therefore, the monitoring device may switch the currently displayed scoring detail interface as shown in fig. 8 to another scoring detail interface as shown in fig. 9. For another example, assuming that the monitoring device receives a click operation of the shortcut control 83 shown in fig. 8 by the user, an interface switching instruction may be obtained, and according to the interface switching instruction, the currently displayed scoring detail interface shown in fig. 8 is switched to another scoring detail interface shown in fig. 9 corresponding to the shortcut control.

In an embodiment, specifically, the description may be given by taking fig. 9 and fig. 8 as an example, for example, assuming that a current display interface of the monitoring device is a scoring detail interface as shown in fig. 9, if the monitoring device receives a sliding operation 91 performed by a user on the scoring detail interface shown in fig. 9, the monitoring device may acquire that the number of touch points corresponding to the sliding operation 91 is 1, and the touch direction is horizontal to the right. The monitoring device may determine that the type of the interface switching is slave interface switching, and acquire that the target slave interface is the scoring detail interface shown in fig. 8 according to the slave interface switching direction, so that the monitoring device may switch the currently displayed scoring detail interface shown in fig. 9 to the scoring detail interface shown in fig. 8. For another example, assuming that the monitoring device obtains a click operation of the user on the shortcut control 92 shown in fig. 9, the monitoring device may obtain an interface switching instruction, and the monitoring device may respond to the interface switching instruction to switch the currently displayed scoring detail interface shown in fig. 9 to the scoring detail interface shown in fig. 8 corresponding to the shortcut control 92.

In the embodiment of the invention, the monitoring equipment can acquire the corresponding interface switching instruction by receiving the click operation of the user on the shortcut control on the user interface, and respond to the interface switching instruction to switch the current display interface to the interface corresponding to the shortcut control. By the mode, the method and the system realize the quick switching operation of the monitoring equipment interface, and improve the monitoring data checking efficiency of the user.

In the monitoring device mentioned in this embodiment, the at least one physiological parameter signal may be obtained by a sensor accessory connected to the patient during a first time period, and the parameter data including the at least one physiological parameter may be generated based on the obtained at least one physiological parameter signal. And displaying the parameter data of the at least one physiological parameter to obtain a display interface.

Herein, the at least one physiological parameter signal may be at least one of temperature (Temp), diastolic blood pressure, systolic blood pressure (BP-S), Heart Rate (HR), Respiratory Rate (RR), consciousness level, blood oxygen (SpO2), oxygen concentration (supp.o2), brain electricity and other physiological parameter signals collected by the sensor accessory. Then, according to the at least one physiological parameter signal, waveforms and/or values corresponding to various physiological parameters such as body temperature (Temp), blood pressure diastolic pressure, systolic pressure (BP-S), Heart Rate (HR), Respiratory Rate (RR), consciousness level, blood oxygen (SpO2), oxygen concentration (supp. o2), brain electricity, and the like can be obtained.

In the present embodiment, the parameter data including at least one physiological parameter is generated according to at least one physiological parameter signal obtained in a time period, and it is understood that, based on the at least one physiological parameter signal obtained in a time period, waveforms and/or values corresponding to a plurality of physiological parameters, such as body temperature (Temp), diastolic blood pressure (diastolic blood pressure), systolic blood pressure (BP-S), Heart Rate (HR), Respiratory Rate (RR), consciousness level, blood oxygen (SpO2), oxygen concentration (supp.o2), brain electricity, and the like, are calculated, so as to generate the parameter data including at least one physiological parameter. Then, the parameter data may include: the waveform and/or the numerical value respectively correspond to one or more physiological parameters of a plurality of physiological parameters, such as body temperature (Temp), blood pressure diastolic pressure, systolic pressure (BP-S), Heart Rate (HR), Respiratory Rate (RR), consciousness level, blood oxygen (SpO2), oxygen concentration (supp.o2), brain electricity and the like. It is understood that, in one embodiment, the interface may be a large number interface when only the corresponding numerical value of the at least one or more physiological parameters is displayed, and may be a waveform interface when the waveform corresponding to the at least one or more physiological parameters is displayed. Referring to fig. 13A, fig. 13A is an interface diagram of waveforms and/or values of physiological parameters at different times according to an embodiment of the present invention, the waveforms 511 and/or values 512 of at least one physiological parameter at different times can be obtained according to at least one physiological parameter signal obtained within a time period, and the waveforms 511 and/or values 512 at different times are displayed in real time in the first area 51 of the display interface for real-time monitoring of the patient. When only the patient's numerical value 512 information is focused or displayed on the display interface, it may be considered to be presented on the large numerical interface. When the waveform 511 and the numerical value 512 of the patient are simultaneously focused or displayed on the display interface, they can be considered to be presented on the waveform interface. Of course, a trend graph 513 of data in a short time may also exist under the waveform interface, and numerical information corresponding to at least one physiological parameter of interest at different times may be presented in a list manner.

Referring to fig. 13B, fig. 13B is an interface diagram of waveforms and/or values of another physiological parameter at different times according to an embodiment of the present invention, the waveforms 511 and/or values 512 of at least one physiological parameter at different times can be obtained according to at least one physiological parameter signal obtained within a time period, and for the waveforms 511 and/or values 512 at different times, a short-time trend graph or a long-time trend graph can be formed according to short-time or long-time statistics, and the short-time trend graph or the long-time trend graph is displayed at a main position on a display interface of a monitoring device, so that a state trend interface can be formed. Referring to fig. 13B, a short-time trend graph or a long-time trend graph (542) corresponding to various physiological parameters such as body temperature (Temp), blood pressure diastolic pressure, systolic pressure (BP-S), Heart Rate (HR), Respiratory Rate (RR), consciousness level, blood oxygen (SpO2), oxygen concentration (supp. o2), brain electricity, etc. may be provided in the window 55. When the cursor 54 moves to the short time trend change chart or the long time trend change chart (542), the moving cursor 541 moves along with the cursor 54, and when the cursor 54 moves to the short time trend change chart or the long time trend change chart (542) corresponding to the relevant physiological parameter, the corresponding numerical information at the current position is displayed in a text mode. The status trend interface may be formed by displaying the short time trend graph or the long time trend graph (542) in the window 55 of fig. 13B at a primary location on the monitoring device display interface.

The following detailed description is of the scoring interface, scoring details interface, and scoring history interface.

Physiological data corresponding to a plurality of physiological parameters is obtained via a sensor accessory coupled to the patient's body. Generating a plurality of sub-statistical scores corresponding to the plurality of physiological parameters respectively according to the physiological data corresponding to the plurality of physiological parameters in the same period of time; and generating a patient early warning state score according to the plurality of sub-statistical scores.

In the embodiment of the present application, the patient Early Warning status Score may be obtained by using a plurality of scoring criteria such as ews (Early Warning Score), Modified Early Warning Score (MEWS). The ews (Early Warning Score) may also be a Modified Early Warning Score (MEWS), which is obtained by assigning a plurality of commonly used physiological indicators, such as temperature (Temp), systolic pressure (BP-S), Heart Rate (HR), respiratory Rate (RR, respiratory Rate), consciousness level, blood oxygen (SpO2), and oxygen concentration (sup. o2), to corresponding sub-statistical scores, and then evaluating the clinical status or potential risk of the patient using the statistical values of the sub-statistical scores to generate a Warning status Score of the patient. Still alternatively, the EWS in the embodiment of the present application may also refer to a child Early Warning Score (pees), and the like, and the embodiment of the present application does not uniquely limit what type or suitable group of the EWS is. Here, the consciousness level is, for example, LOC (AVPU) -based scoring, i.e., a common method for judging the consciousness state is "AVPU" scoring, and the scoring system divides the consciousness state into four levels: responsive (alert), responsive to verbal (verba) stimulus, responsive to pain (pain) stimulus, and non-responsive. The following explanation takes the MEWS scoring rule as an example. The MEWS scoring has the characteristics of simple application, easy mastering, quick and convenient clinical information acquisition, is not limited by hardware equipment conditions of hospitals or emergency departments, is widely applied to emergency work, accurately judges the illness state of patients in time and better finishes medical work. And grading emergency treatment patients according to MEWS scores, and taking different treatment measures according to grades based on the score of the early warning total score: (1)

the patients can be diagnosed and treated according to the general routine procedures without the risk of potential critical diseases and generally hospitalization, and can be temporarily placed for later treatment in case of emergency. (2)

In other words, the patient has unstable and large changes, and has the risk of "latent critical disease". Emergency doctors should make a first treatment and inform the patients of the relevant conditions in time, and arrange the patients to live into the specialized ward or even the ICU at the right time. (3)>In 9 minutes, the patient is critically ill and the death risk is obviously increased, and the condition allows the patient to be immediately sent to an intensive care unit or a special ward to receive treatment. In addition, the patient should be subjected to dynamic MEWS scoring, a single scoring 2-point person evaluates the scoring 1 time every 4 hours, a single scoring 3-point person evaluates the scoring 1 time every 2 hours, a single scoring 4-point person evaluates the scoring 1 time every 1 hour, and the diagnosis and treatment plan is adjusted in time according to the scoring change. It can be seen that each patient early warning state score is determined by sub-scores corresponding to the plurality of physiological parameters in the same time period.

In one embodiment, in the generating of the plurality of sub-statistical scores corresponding to the plurality of physiological parameters according to the physiological data corresponding to the plurality of physiological parameters, the sub-statistical score corresponding to each physiological parameter is obtained according to the early warning score rule.

In one embodiment, the generating the patient warning state score according to the plurality of sub-statistical scores includes: and calculating to obtain the early warning state score of the patient through weighted summation according to the plurality of sub-statistical scores.

In one embodiment, the patient early warning state score is displayed on a display interface according to the first measurement frequency in a refreshing mode, and a scoring interface is generated. And refreshing and displaying the plurality of sub-statistical scores on a display interface according to a second measuring frequency to generate a score detail interface.

For example, referring to fig. 13A, the scoring interface is obtained by displaying the patient warning state score (e.g., icon 522 in fig. 13A) in real time in the first area 52 on the display interface according to the first measurement frequency.

For example, referring to fig. 13A to 13E, the plurality of sub-statistical scores (e.g., icon 533 in fig. 13A) are displayed in the first area 52 on the display interface in a refreshing manner according to the second measurement frequency, and a score detail interface is obtained.

During this refresh display, the first measurement frequency may be equal to the second measurement frequency, i.e., the patient alert status score and the associated plurality of sub-statistical scores are displayed in the first region 52 in a synchronized refresh display at the same frequency. In addition, in an embodiment, the first measurement frequency is different from the second measurement frequency, and the second measurement frequency is greater than the first measurement frequency. That is, in some embodiments, the refresh display frequency of the plurality of sub-statistical scores is greater than the refresh display frequency of the patient alert status score. In this embodiment, the plurality of sub-statistical scores may not be obtained at the same time according to different obtaining times of the plurality of physiological parameters corresponding to the plurality of sub-statistical scores, and therefore, the generation time of the patient early warning state score may be later than the plurality of sub-statistical scores, and then the display of the plurality of sub-statistical scores may be refreshed and updated.

In some embodiments, referring to fig. 13A, a display in a scoring interface is shown, wherein the processor of the monitor refreshes the patient alert status score in a first area 52 on the display interface at a first measurement frequency by:

drawing a real-time status icon 522 in the second display area 52; and the combination of (a) and (b),

and displaying the real-time status icon 522, and sequentially assigning the display result of the real-time status icon 522 to a value corresponding to the patient early warning status score according to a first measurement frequency, so as to refresh and display the patient early warning status score in the first area 52 on the display interface according to the first measurement frequency.

Of course, the waveforms 511 and values 512 of the relevant physiological parameters can be refreshed in real time in the second region 51, except for the first region 52, on the display interface.

For example, the display result of the real-time status icon 522 described above is assigned a patient pre-alarm status score of "7". A plurality of patient warning state scores are obtained one by one according to a first measurement frequency, for example, a patient warning state score of "1" is obtained at 7:00, a patient warning state score of "1" is obtained at 9:00, a patient warning state score of "1" is obtained at 11:00, a patient warning state score of "4" is obtained at 13:00, a patient warning state score of "4" is obtained at 14:00, and a patient warning state score of "7" is obtained at 15:00, so that when the patient warning state scores are displayed in a first area 52 on the display interface in a refresh manner according to the first measurement frequency, the display result of the real-time state icon 522 is sequentially displayed as "1" at 7:00, as "1" at 9:00, as "1" at 11:00, as "4" at 13:00, as "4" at 14:00, and as "7" at 15: 00.

Highlighting the real-time status icon when the patient pre-alarm status score is greater than or equal to a total score threshold. For example, when the patient pre-alarm status score is greater than or equal to the total score threshold 4, the real-time status icon 522 at the corresponding time is highlighted, and the real-time status icon 522 may be highlighted by changing the size attribute value, the color attribute value, and the like.

In some embodiments, the above method further comprises the steps of:

the processor determines that at least one sub-statistical score exceeds a sub-score threshold value in the early warning state scores of the patients; and outputting prompt information that at least one sub-statistical score exceeds a sub-score threshold exists in the early warning state scores of the patients.

For example, in fig. 13A to 13E, in the first display area 52, the prompt information is output along with the refresh display of the real-time status icon 522 according to the patient's early warning status score. In fig. 13A to 13E, a property page 523 is provided, and a prompt message indicating that at least one sub-statistical score exceeds a sub-score threshold in the patient early warning status scores is written in the property page 523 for reminding. When the display result of the real-time status icon 522 is updated along with the calculation result of the early warning status score of the patient, the prompt information is also updated correspondingly.

Of course, in the property page 523, in addition to the prompt information that at least one sub-statistical score exceeds the sub-score threshold in the patient early warning status scores with the update of the real-time status icon 522, the score range where the current patient early warning status score is located, the information that should be focused within the current score range, and the prompt event that prompts the user to know may be updated with the update of the real-time status icon 522.

The sub-score thresholds mentioned in this embodiment may be 0, 1, 3, etc. Of course, in the prompt information associated with the pictogram icon, not only the related physiological parameter whose sub-statistical score exceeds the sub-score threshold in the patient early warning state score and the sub-statistical score corresponding thereto, but also the related physiological parameter and the sub-statistical score corresponding thereto which are of particular interest to the user may be displayed. For example, in fig. 13B, the prompt displayed with the update of the real-time status icon 522 may be the corresponding real-time values of HR, Respiratory Rate (RR), blood oxygen (SpO2), and oxygen concentration (supp.o2) of particular interest, and their corresponding sub-statistical scores.

In some embodiments, the step of refreshing the interface for displaying the plurality of sub-statistical score generation score details comprises:

drawing a plurality of sub-score display icons in the first region, each sub-score display icon being associated with a physiological parameter; and the combination of (a) and (b),

and displaying the sub-score display icons, and sequentially assigning the display results of the sub-score display icons to the generated sub-statistical scores according to a second measurement frequency.

For example, referring to fig. 13A to 13E, a plurality of sub-score display icons 526 are drawn in the first area 52, and each sub-score display icon 533 is associated with one physiological parameter, such as HR, Respiratory Rate (RR), blood oxygen (SpO2), oxygen concentration (supp. o2), body temperature, and BP-S, LOC (AVPU) corresponding to one sub-score display icon 526 respectively. Each sub-score display icon 526 comprises a bar 532 and a numerical display area 533, the numerical display area 533 is updated according to the score association of the sub-statistical scores, the display result of the sub-score display icon 526 can also be displayed by using the bar 532, the length of the bar 532 is associated with the numerical value of the related sub-statistical score, and the orientation of the bar reflects the variation trend of the related sub-statistical score relative to the benchmark threshold. In addition, a scale 525 of the sub-statistical score standard is provided above the sub-score display icon.

As shown in fig. 13A to 13E, the display result of the sub-score display icon 526 is displayed by a bar, the length of the bar is related to the value of the related sub-score, and the orientation of the bar reflects the change trend of the related sub-score with respect to a reference threshold, where the reference threshold is the sub-score being 0. The single physiological parameter has 7 sections of 3 points high, 0 point and 3 points low, namely 3 points low (red), 2 points low (orange), 1 point low (yellow), zero (white), 1 point high (yellow), 2 points high (orange) and 3 points high (red), different values of each physiological parameter correspond to different score sections, the length of a bar corresponds to different score sections, the color of the bar corresponds to different score section colors, the score section where the single physiological parameter is located is represented by a transverse bar in an interface, the score of the bar is higher if the bar is longer, for example, the heart rate HR is smaller than or equal to 40 or 2 points low, the bar is leftward, the heart rate HR is 2 points high between 111-129, the bar graph is rightward, and the score of each physiological parameter is displayed at the central position. Whether the relevance sub-score is high or low relative to the benchmark threshold 0 is reflected by the orientation of the bar.

In addition, the real-time values corresponding to the relevant physiological parameters are correspondingly displayed in the display area of the sub-score display icon 526. In some embodiments, the real-time values corresponding to the relevant physiological parameters displayed in the display area of the sub-score display icon 526 are real-time collected values corresponding to the time when the sub-statistical score is calculated.

In addition, the display area of the sub-score display icon 526 further includes an edit icon 534, and the user enters a setting interface of the relevant score standard and a setting interface of the relevant reminding event and the attention information by clicking the edit icon 534, and certainly, can enter the relevant interface by clicking the edit icon 534 to set whether the corresponding physiological parameter needs to be attended, needs to be included in the score of the early warning state of the patient, needs to be displayed, and other attribute states.

In some embodiments, the above method further comprises:

determining associated state attention prompt information according to the grading range of the early warning state grading of the patient;

drawing a prompt message attribute page in the first area; and the combination of (a) and (b),

and outputting and displaying the state attention prompt information on the prompt information attribute page.

The state attention information includes one of a reminding attention item, a score range of an indication score, a reminding event, attention information and the like corresponding to the score range of the corresponding early warning total score.

Still further, the above method further comprises:

determining a related rendering attribute according to the scoring range of the patient early warning state score;

and adjusting the display effect of the prompt information attribute page according to the rendering attribute.

Referring to fig. 13A to 13E, a prompt information attribute page 523 is drawn in the first area 52, and according to the score range of the patient early warning state score, associated state attention prompt information is determined, for example, the patient early warning state score displayed at the current time is 7, and the score range is 7-14, so that the determined associated state prompt information includes prompt information that at least one sub-statistical score exceeds the sub-score threshold in the patient early warning state score, the score range of the current patient early warning state score, information that should be paid attention in the current score range, a prompt event prompting the user to know, and the like. As shown by reference numeral 524 in the figure, in the embodiment, 4 scoring ranges are provided, which correspond to different status attention prompt messages, and the prompt message attribute page 523 containing the attention prompt messages in different statuses is switched according to the different scoring ranges as the icon 522 is displayed in a refreshing manner according to the corresponding numerical value of the patient early warning status score. Moreover, according to the score range in which the patient early warning state score is located, the associated rendering attribute may also be determined, the 4 score ranges (e.g., the score ranges are 0-4, 4-7, 7-14, >14) provided in the embodiment respectively correspond to the 4 rendering attribute values, as shown in the differentiated display of the drawing reference numeral 524, based on the score range in which the patient early warning state score is located at the current time, the associated rendering attribute may be searched, and the display effect of the prompt information attribute page may be correspondingly refreshed.

In addition, a progress bar 521 is included in the first region 52 for prompting the next time the patient warning status score is calculated.

Also included in the first region 52 is a manual calculation button 531, by which a user can initiate statistical calculations regarding the patient's pre-alarm status score at any time by clicking on the manual calculation button 331.

A setting button 527 is further included in the first area 52, and a user can enter the attribute setting window by clicking the setting button 527 to select another function, or perform functions such as page setting and mode setting.

In some embodiments, the sub-score display icons 526 correspond to partial parameters for determining the physiological parameters in the early warning status score, and the sub-scores corresponding to the partial parameters respectively exceed a sub-score threshold. That is, to reduce screen occupancy, which may be used to determine only some of the plurality of physiological parameters in the patient warning status score, only the sub-score display icons 526 associated with some of the parameters are displayed in the first region 52.

In the embodiment, the waveform and the numerical value of the physiological parameter can be obtained in real time, and meanwhile, the state of the patient is statistically scored based on the rule of early warning, so that the user is taken out from the situation that the waveform and the numerical value of the complex physiological parameter are read in real time, and the current state and the critical grade of the patient can be rapidly known by the user through simple numerical statistical analysis and color reminding. Furthermore, corresponding prompts of reminding events and attention information can be provided according to critical grade requirements, the utilization rate of the monitor is greatly improved, the attention degree of common patients is improved, and the use of the monitor is simplified.

With continued reference to fig. 13A-13E, in the corresponding region (which may be in the first region or the second region) of the display interface, a trend graph of the historical patient warning state score is also displayed, forming a score history interface. In one embodiment, the scoring history interface may be gradually deployed from below the display interface to the position shown in fig. 13A-13E.

For example, the time axis 528 is plotted in a trend graph area on the display interface; and outputting and displaying the patient early warning state scores in corresponding time periods at corresponding positions on the time axis 528 to obtain a plurality of icons, and sequentially arranging the icons on the time axis 528 along time change to form a change trend graph of historical patient early warning state scores and form a score history interface. The distance between corresponding locations displaying the patient early warning status score on a timeline is inversely related to the first measurement frequency. For example, in one embodiment, the first measurement frequency and/or the second measurement frequency are adjusted according to the relationship between the patient early warning state score and the total score threshold. Particularly, when the first measuring frequency is equal to the second measuring frequency and the early warning state score of the patient is greater than or equal to the total score threshold value, the first measuring frequency and the second measuring frequency are synchronously increased.

In one embodiment, a processor receives a plurality of physiological parameters acquired from a real-time monitored subject over a first time period, obtaining a first set of physiological data; obtaining at least one first patient pre-alarm state score at a first frequency based on the first set of physiological data; receiving a plurality of physiological parameters acquired from the real-time monitored subject within a second time period to obtain a second set of physiological data; obtaining at least one second patient pre-alarm state score at a second frequency based on the second set of physiological data; and outputting the at least one first patient early warning state score and the at least one second patient early warning state score in sequence over time. If any one of the first patient early warning state scores is greater than or equal to a total score threshold value, the first frequency is adjusted to be a second frequency, wherein the second frequency is higher when the first patient early warning state score is larger. In one embodiment, the first time period is different from and does not coincide with the second time, but has temporal continuity. The time periods referred to herein are all inclusive of at least one time instant.

Referring to fig. 13A to 13E, the at least one first patient warning state score is outputted at least one first position on the time axis 528, so as to obtain at least one first icon 529-1;

correspondingly outputting the at least one second patient warning state score at least one second position on the time axis 528 to obtain at least one second icon 529-2; and the combination of (a) and (b),

and sequentially arranging the first icon 529-1 and the second icon 529-2 along time variation on the time axis according to the acquisition time corresponding to the at least one first patient early warning state score and the at least one second patient early warning state score to form a trend graph of historical patient early warning state scores.

Specifically, the first icon or the second icon may be represented by a graphical specific icon (e.g., a circled number in fig. 13A to 13E), a straight line, a dot, or text. And a trend change chart of the corresponding historical early warning total score can be obtained by displaying the first icon and the second icon. Further, in one embodiment, in the trend graph, the distance interval between two adjacent first positions on the time axis 528 is related to the first frequency, and the distance interval between two adjacent second positions on the time axis is related to the second frequency. For example, referring to fig. 13A to 13E, first warning total scores 1, 2, 4 are respectively and correspondingly marked at first positions corresponding to 7:00, 9:00, 11:00, 13: 00; and second early warning total scores 4 and 7 are marked at second positions corresponding to 14:00 and 15:00 in sequence, and it can be seen that the time interval corresponding to the first patient early warning state score is two hours (namely, a first frequency), and the time interval corresponding to the second patient early warning state score is one hour (namely, a second frequency), so that the adjacent interval of the first position (namely 529-1) on the time axis is related to the first frequency, and the adjacent interval of the second position (namely 529-2) on the time axis is related to the second frequency.

In addition, in one embodiment, when the first patient warning state score or the second patient warning state score is greater than or equal to a total score threshold, the corresponding first icon or second icon is highlighted. For example, referring to fig. 13A to 13E, the first icon and the second icon drawn at the first position corresponding to 13:00 and the second position corresponding to 14:00 and 15:00 employ a distinguishing highlight, and the distinguishing highlight may be obtained by modifying attribute values such as a rendering color of the icon, a shape and a size of the icon, and the like.

In addition, because each patient early warning state score is derived from sub-scores corresponding to a plurality of physiological parameters, for example, sub-scores corresponding to a plurality of physiological parameters can be summed or weighted to obtain the patient early warning state score. Therefore, in some of these embodiments, the first patient warning state score or the second patient warning state score is determined by sub-scores of a plurality of physiological parameters.

The prompt information can be highlighted on a trend graph of the historical patient early warning state score. For example, referring to fig. 13A to 13E, on the trend graph region, corresponding prompt information is displayed at a position (i.e., 529-2) related to the second patient early warning state score, the prompt information includes prompt information 530 that the sub-statistical score exceeds (is greater than or equal to) the sub-score threshold 3 in the second patient early warning state score, the highlight prompt is displayed by marking the sub-score threshold 3 in fig. 13A to 13E, or the number of parameters that the sub-score exceeds (is greater than or equal to) the sub-score threshold 3 in the first early warning total score or the second early warning total score is marked. For example, the prompt message may also be related physiological parameters whose sub-scores exceed (are greater than or equal to) the sub-score threshold in the second patient early warning state score, for example, in fig. 13A to 13E, the "HR ═ 140" of the markers respectively at time 13:00, 14:00, and 15:00 indicates that the sub-score corresponding to the physiological parameter HR exceeds the sub-score threshold 3 in the total early warning scores obtained at time 13:00, 14:00, and 15:00, so as to perform special warning.

The frequency (for example, the first measurement frequency, the second measurement frequency, and the first frequency and the second frequency mentioned below) in the embodiment of the present application may be understood as the number of times the patient warning state score is obtained within a predetermined period of time (for example, every hour), or may be the number of times the patient warning state score is obtained within a predetermined period of time (for example, every hour), and the like. The first frequency as in the embodiment of the present application may be to obtain the EWS total score (i.e., the first warning total score) every two hours. The patient warning status score herein may be the aforementioned EWS total score.

By implementing the embodiment of the application, the score of the early warning state of the first patient acquired at the first frequency can be displayed, the score of the early warning state of the second patient acquired at the second frequency is larger than the total score of the first early warning acquired at the first frequency, the change state of the body of the medical staff in the preset time can be clearly prompted, the condition that the medical staff urgently needs related values (such as the total score of the EWS) and manually corresponds to historical values is effectively avoided, the working efficiency of the medical staff is improved, the body state of the medical staff paying attention to the patient can be obviously improved in time, and the monitoring efficiency of the early warning score display device is improved.

A setting button 527 is further included in the first area 52, and a user can enter the attribute setting window by clicking the setting button 527 to select another function, or perform functions such as page setting and mode setting.

Referring to fig. 13A-13B, a number of shortcut controls 538, 535, 536 are provided. As shown in fig. 13A, the scoring detail interface (including at least one icon 526) may be gradually expanded in the scoring interface by pulling the shortcut control 538 in direction 539 to be displayed on the display interface, thereby displaying the scoring detail interface as shown in fig. 13B. Next, fig. 13C is an interface diagram of waveforms and/or values of another physiological parameter at different times according to the embodiment of the present invention, for example, fig. 13C continues to pull the shortcut control 538 along the direction 539, or pulls the shortcut control 536 at the bottom of the score detail interface, and may further continue to output a score history interface to be displayed in the display interface, for example, fig. 13D displays the score history interface, and fig. 13D is an interface diagram of a score history according to the embodiment of the present invention. By pulling shortcut control 535 in direction 540, the state trend interface can be gradually expanded in the scoring interface to be displayed on the display interface, so that the state trend interface is displayed as shown in fig. 13E, where fig. 13E is an interface diagram for displaying a state trend according to an embodiment of the present invention. Of course, the state trend interface may be presented based on the gesture of pulling shortcut control 535 in direction 540 being different (e.g., different distance of sliding along the display interface) such that a short time trend graph or a long time trend graph may be expanded. Of course, based on the gesture of pulling the shortcut control 535 along the direction 540, the short-time trend change chart or the long-time trend change chart may be sequentially expanded according to the change of the sliding distance of the gesture along the display interface, so as to present the state trend interface.

Therefore, in one embodiment, the aforementioned determining the type and direction of interface switching according to the editing gesture, and performing switching processing on the current display interface according to the direction of interface switching according to the type of interface switching at least includes one of the following steps:

expanding any one or more of a state trend interface, a scoring detail interface and a scoring history interface from the edge of the main interface according to the editing gesture;

gradually unfolding or unfolding a scoring interface along a first direction from the edge of the main interface according to the editing gesture;

gradually unfolding or unfolding a scoring detail interface along a second direction from the scoring interface according to the editing gesture;

gradually unfolding or unfolding a state trend interface from the grading interface or the grading detail interface along a third direction according to the editing gesture;

gradually expanding or expanding a scoring history interface along a second direction from the scoring interface or the scoring detail interface according to the editing gesture;

and sequentially unfolding the short-time trend change chart and the long-time trend change chart in the state trend interface along the third direction along with the sliding of the editing gesture on the display interface.

The first direction, the second direction and the third direction may be the same or different. The first direction, the second direction and the third direction determine the sliding direction of the editing gesture on the display interface. In addition, in one embodiment, the third direction is different from the second direction and the first direction. That is, the state trend interface expands laterally from the display interface, while at least one of the scoring interface, the scoring detail interface, and the scoring history interface may expand vertically from the display interface. Of course, the first direction may be different from the second direction, that is, the first direction may be from top to bottom in the longitudinal direction on the display interface, and the second direction may be from bottom to top in the longitudinal direction on the display interface.

The patient warning status score may be an EWS score. The detailed grading historical information of each parameter of the patient is checked by sliding on a single finger of a grading detail interface (EWS grading detail plate), the actual idea of the medical staff is realized in a simplest and easiest way, the work of the medical staff is matched more efficiently, and the learning cost of the medical staff for the product is saved; in a scoring history interface (such as an EWS scoring history detail page of a patient), a single finger slides down to return to the scoring interface (an EWS comprehensive scoring opinion page) so that medical personnel can check related information such as processing suggestions and the like by the fastest method. In a scoring history interface (such as a patient EWS scoring history detail page), a single finger continues to slide to the right to view a patient state single parameter more details (such as a state trend interface), and an actual clinical scene is fully considered in a product interaction gesture.

Referring to fig. 10 in detail, fig. 10 is a schematic structural diagram of a monitoring device according to an embodiment of the present invention. The monitoring device in the embodiment as shown in the figure may comprise: one or more data interfaces 1001, one or more processors 1002, a memory 1003, a user interface 1004, the data interface 1001, the processor 1002 and the memory 1003 being interconnected, wherein the memory 1003 is configured to store instructions and the processor 1002 is configured to execute instructions stored by the memory 1003. Wherein the memory 1003 is used for storing a computer program, the computer program comprises program instructions, and the processor 1002 is configured to call the program instructions to execute the following steps:

acquiring at least one physiological parameter signal in a first time period through a sensor accessory connected with a patient, and generating parameter data containing at least one physiological parameter according to the acquired at least one physiological parameter signal;

displaying parameter data of the at least one physiological parameter;

receiving the editing operation of a user on the current display interface of the monitoring equipment;

acquiring an editing gesture corresponding to the editing operation;

determining the type and the direction of interface switching according to the editing gesture, wherein the type of interface switching comprises the following steps: a master interface switching type or a slave interface switching type;

and switching the current display interface according to the type of the interface switching and the direction of the interface switching, wherein the slave interface comprises a statistical analysis result of the physiological data displayed on the basis of the master interface.

In one embodiment, the monitoring device may further adopt the structure described in the foregoing, which can be seen in detail in the foregoing.

Further, the processor 1002 of the monitoring device is further configured to invoke program instructions to perform the steps of:

acquiring the number of touch points included in the editing gesture;

if the number of the touch points is larger than a preset threshold value, determining that the type of the interface switching is a main interface switching type, and determining the touch direction as a main interface switching direction;

and if the number of the touch points is smaller than or equal to a preset threshold value, determining that the type of the interface switching is a slave interface switching type, and determining the touch direction as a slave interface switching direction.

Further, the processor 1002 of the monitoring device is further configured to invoke program instructions to perform the steps of:

if the interface switching type is a main interface switching type, determining a first main interface corresponding to the current display interface;

acquiring a second main interface according to the main interface switching direction;

and switching the current display interface to the second main interface.

Further, the processor 1002 of the monitoring device is further configured to invoke program instructions to perform the steps of:

if the type of the interface switching is a slave interface switching type, acquiring a target slave interface according to the slave interface switching direction;

and switching the current display interface into the target slave interface.

Further, the main interface includes: a large digital interface and/or a waveform interface; the slave interface is subordinate to the master interface and comprises any one or more of a state trend interface, a grading detail interface and a grading history interface.

Further, the processor 1002 of the monitoring device is further configured to invoke program instructions to perform the steps of:

and if the click operation of the user on the shortcut control is received, switching the current display interface to the interface corresponding to the shortcut control.

Further, when determining the type and direction of interface switching according to the editing gesture, and performing switching processing on the current display interface according to the type of interface switching and the direction of interface switching according to the type of interface switching, the processor 1002 of the monitoring device is further configured to invoke a program instruction, and perform one of the following steps:

expanding any one or more of a state trend interface, a scoring detail interface and a scoring history interface from the edge of the main interface according to the editing gesture;

expanding a scoring interface from the edge of the main interface along a first direction according to the editing gesture;

deploying a scoring detail interface from the scoring interface in a second direction according to the editing gesture;

expanding a state trend interface from the scoring interface or the scoring detail interface along a third direction according to the editing gesture;

expanding a scoring history interface in a second direction from the scoring interface or scoring detail interface according to the editing gesture;

and sequentially unfolding the short-time trend change chart and the long-time trend change chart in the state trend interface along the third direction along with the sliding of the editing gesture on the display interface.

Further, the third direction and the second direction are different.

It should be understood that, in the embodiment of the present invention, the Processor 1002 may be a Central Processing Unit (CPU), and the Processor may also be other general-purpose processors, Digital Signal Processors (DSPs), Application Specific Integrated Circuits (ASICs), Field Programmable Gate Arrays (FPGAs) or other Programmable logic devices, discrete Gate or transistor logic devices, discrete hardware components, and the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.

The data interface 1001 may include a touch pad, a microphone, etc., and the user interface 1004 may include a display (LCD, etc.), a speaker, etc.

The memory 1003 may include both read-only memory and random-access memory, and provides instructions and data to the processor 1002. A portion of the memory 1003 may also include non-volatile random access memory. For example, the memory 1003 may also store information of device types.

In a specific implementation, the data interface 1001, the processor 1002, and the memory 1003 described in this embodiment of the present invention may execute the implementation described in the embodiment of fig. 5 or fig. 6 of the interface operation method applied to the monitoring device provided in this embodiment of the present invention, and may also execute the implementation of the monitoring device described in this embodiment of the present invention, which is not described herein again.

According to the embodiment of the invention, the monitoring device obtains at least one physiological parameter signal in a first time period through a sensor accessory connected with a patient, generates parameter data containing at least one physiological parameter according to the obtained at least one physiological parameter signal, and displays the parameter data of the at least one physiological parameter. The monitoring device can receive the editing operation of a user on the current display interface of the monitoring device, obtain the editing gesture corresponding to the editing operation, and determine the type and the direction of interface switching according to the editing gesture, so that the current display interface is switched according to the type of interface switching and the direction of interface switching. By the mode, the method and the system realize the quick switching operation of the monitoring equipment interface, and improve the monitoring data checking efficiency of the user.

Based on the foregoing related embodiments, there is further provided an interface operation method applied to a monitoring device in the embodiments, as shown in fig. 14, which may include the following steps:

step S141, obtaining at least one physiological parameter signal in a first time period by a sensor accessory connected to a patient, and generating a real-time waveform and/or a real-time value containing at least one physiological parameter according to the obtained at least one physiological parameter signal. And step S142, displaying the real-time waveform and/or the real-time numerical value of the at least one physiological parameter on a display interface.

Herein, the at least one physiological parameter signal may be at least one of temperature (Temp), diastolic blood pressure, systolic blood pressure (BP-S), Heart Rate (HR), Respiratory Rate (RR), consciousness level, blood oxygen (SpO2), oxygen concentration (supp.o2), brain electricity and other physiological parameter signals collected by the sensor accessory. Then, according to the at least one physiological parameter signal, real-time waveforms and/or real-time values corresponding to various physiological parameters such as body temperature (Temp), blood pressure diastolic pressure, systolic pressure (BP-S), Heart Rate (HR), Respiratory Rate (RR), consciousness level, blood oxygen (SpO2), oxygen concentration (supp. o2), brain electricity and the like can be obtained.

In the present embodiment, the parameter data including at least one physiological parameter is generated according to at least one physiological parameter signal obtained in a time period, and it is understood that, based on the at least one physiological parameter signal obtained in a time period, real-time waveforms and/or real-time values corresponding to a plurality of physiological parameters, such as body temperature (Temp), diastolic blood pressure (diastolic blood pressure), systolic blood pressure (BP-S), Heart Rate (HR), Respiratory Rate (RR), consciousness level, blood oxygen (SpO2), oxygen concentration (supp. o2), brain electricity, and the like, are calculated, so as to generate the parameter data including at least one physiological parameter. As shown in fig. 13A, the waveforms 511 and/or the values 512 at different times are displayed in real time in the first area 51 of the display interface, and the waveforms 511 and/or the values 512 are real-time waveforms and/or real-time values.

And step S143, receiving the editing operation of the user on the current display interface of the monitoring device. See the above description about steps S601 and S503.

Step S144, acquiring an editing gesture corresponding to the editing operation. In some embodiments, the editing gesture is a swipe operation. See the above description related to step S504.

And S145, determining the switching direction according to the editing gesture.

In the embodiment of the invention, the monitoring equipment can determine the direction of interface switching according to the acquired editing gesture. The slave interface herein may include a statistical analysis result based on the physiological data displayed by the master interface, and the statistical analysis result is presented as any one or more of a state trend interface, a scoring detail interface, and a scoring history interface.

The types of interface switching include: a master interface switch type or a slave interface switch type. It should be noted that the master interface switching type is switching between master interfaces, and the slave interface switching type is switching between slave interfaces, or switching between a master interface and a slave interface. In an embodiment, the monitoring device may obtain, according to the obtained editing gesture, the number of touch points included in the editing gesture, and if the number of touch points is greater than a preset threshold, may determine that the type of interface switching is a primary interface switching type, and determine a touch direction included in the editing gesture as a primary interface switching direction. If the number of the touch points is smaller than or equal to the preset threshold, the type of interface switching can be determined to be a slave interface switching type, and the touch direction is determined to be a slave interface switching direction. In one embodiment, the editing gesture may be a sliding operation, and the switching direction is a sliding direction of the gesture on the display interface.

And step S146, expanding and displaying a slave interface on the display interface along the switching direction, wherein the slave interface comprises a statistical analysis result based on the real-time waveform and/or the real-time numerical value.

In some embodiments, the slave interface includes any one or more of a state trend interface, a scoring detail interface, and a scoring history interface.

In some embodiments, the displaying the slave interface on the display interface in the switching direction includes at least one of the following modes:

in the first mode, the scoring interface is unfolded from the edge of the display interface along a first direction. For example, the first direction may be from the edge of the display interface from top to bottom, or from bottom to top, or from left to right, or from right to left.

And in a second mode, expanding the scoring detail interface along a second direction. For example, likewise, the second direction referred to herein may be the same as the first direction. Referring to fig. 13A, the scoring details interface may be deployed from the edge of the display interface, from bottom to top, in direction 539. And gradually expanding the display on the display interface from the interface (such as a scoring detail interface) along with the sliding of the sliding gesture on the display interface. The gradual expansion referred to herein means that the statistical result from the interface is gradually displayed on the display interface as the slide gesture slides on the display interface. Of course, the scoring details interface may also be spread across the display interface from left to right along the direction 540 from the edge of the display interface. Second, the second direction may also be from the edge of the display interface from bottom to top, or from right to left. In one embodiment, the scoring detail interface is deployed in a second direction from an edge of the scoring interface.

In a second mode, the state trend interface is deployed in a third direction. For example, the third direction mentioned herein may be the same as the first direction and the second direction, and may be different from the first direction and the second direction. Referring to FIG. 13A, the state trend interface may be unrolled from bottom to top along direction 539 from an edge of the display interface. And gradually expanding and displaying the interface (such as a state trend interface) on the display interface along with the sliding of the sliding gesture on the display interface. Of course, the state trend interface may also be unrolled onto the display interface from left to right along the direction 540 from the edge of the display interface, with the result shown in FIG. 13E. Second, the third direction may also be from the edge of the display interface from bottom to top, or from right to left. In one embodiment, the scoring detail interface is deployed in a third direction from an edge of the scoring interface. In one embodiment, the third direction is perpendicular to the first direction or the second direction.

And in a third mode, the grading history interface is unfolded along the second direction. Referring to fig. 13C, the scoring history interface may be deployed in a direction (e.g., a small arrow above 536 in fig. 13C) from the bottom to the top of the edge of the display interface. As the swipe gesture swipes across the display interface, the display interface is gradually expanded from the interface (e.g., the scoring history interface). Of course, the scoring history interface may also be spread across the display interface from left to right along the direction 540 from the edge of the display interface. Second, the second direction may also be from the edge of the display interface from bottom to top, or from right to left. In one embodiment, the scoring history interface is deployed in a second direction from an edge of the scoring interface or scoring detail interface.

And in a fourth mode, along with the sliding of the editing gesture on the display interface, sequentially developing the short-time trend variation graph and the long-time trend variation graph in the state trend interface along the third direction. See in particular the preceding description relating to fig. 13A to 13E.

In an embodiment of the present invention, the monitoring device may obtain at least one physiological parameter signal in a first time period through a sensor accessory connected to the patient, generate a real-time waveform and/or a real-time value including at least one physiological parameter according to the obtained at least one physiological parameter signal, and display the real-time waveform and/or the real-time value of the at least one physiological parameter on the display interface. The monitoring device can receive an editing operation of a user on a current display interface of the monitoring device, acquire an editing gesture corresponding to the editing operation, determine a switching direction according to the editing gesture, and display a slave interface on the display interface along the switching direction, wherein the slave interface comprises a statistical analysis result based on the real-time waveform and/or the real-time numerical value. By the mode, the monitoring equipment interface can be switched quickly, and the monitoring data checking efficiency of a user is improved.

Based on the method, the monitoring device is also provided, and the monitoring device comprises:

a parameter measurement circuit electrically connected to a sensor accessory disposed on a patient's body for obtaining at least one physiological parameter signal;

a processor and a memory;

the memory is used for storing computer programs, and the processor is used for implementing the following steps when executing the computer programs stored in the memory:

generating a real-time waveform and/or a real-time numerical value containing at least one physiological parameter according to the obtained at least one physiological parameter signal;

displaying the real-time waveform and/or real-time numerical value of the at least one physiological parameter on a display interface;

receiving the editing operation of a user on the current display interface of the monitoring equipment;

acquiring an editing gesture corresponding to the editing operation;

determining a switching direction according to the editing gesture;

and displaying a slave interface expansion on the display interface along the switching direction, wherein the slave interface comprises a statistical analysis result based on the real-time waveform and/or the real-time numerical value.

In some embodiments, the slave interface includes any one or more of a state trend interface, a scoring detail interface, and a scoring history interface.

In some embodiments, the processor is configured to cause the display of the slave interface spread in the switch direction on the display interface by at least one of:

expanding a scoring interface from an edge of the display interface along a first direction;

expanding a scoring detail interface along a second direction;

expanding the state trend interface along a third direction;

expanding a grading history interface along a second direction; and the combination of (a) and (b),

and sequentially unfolding the short-time trend change chart and the long-time trend change chart in the state trend interface along the third direction along with the sliding of the editing gesture on the display interface.

In some embodiments, the editing gesture is a swipe operation.

In some embodiments, the third direction is perpendicular to the second direction or the first direction.

In an embodiment of the present invention, a monitoring device obtains at least one physiological parameter signal in a first time period through a sensor accessory connected to a patient, generates a real-time waveform and/or a real-time value including at least one physiological parameter according to the obtained at least one physiological parameter signal, and displays the real-time waveform and/or the real-time value of the at least one physiological parameter on a display interface. The monitoring device can receive an editing operation of a user on a current display interface of the monitoring device, acquire an editing gesture corresponding to the editing operation, determine a switching direction according to the editing gesture, and display a slave interface on the display interface along the switching direction, wherein the slave interface comprises a statistical analysis result based on the real-time waveform and/or the real-time numerical value. By the mode, the monitoring equipment interface can be switched quickly, and the monitoring data checking efficiency of a user is improved.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, which can be stored in a computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. The storage medium may be a magnetic disk, an optical disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), or the like.

The above disclosure is intended to be illustrative of only some embodiments of the invention, and is not intended to limit the scope of the invention.

Claims (26)

1. An interface operation method applied to a monitoring device is characterized by comprising the following steps:

   acquiring at least one physiological parameter signal in a first time period through a sensor accessory connected with a patient, and generating parameter data containing at least one physiological parameter according to the acquired at least one physiological parameter signal;

   displaying parameter data of the at least one physiological parameter;

   receiving the editing operation of a user on the current display interface of the monitoring equipment;

   acquiring an editing gesture corresponding to the editing operation;

   determining the type and the direction of interface switching according to the editing gesture, wherein the type of interface switching comprises the following steps: a master interface switching type or a slave interface switching type;

   according to the type of the interface switching, switching the current display interface according to the direction of the interface switching,

   wherein, the slave interface comprises a statistical analysis result based on the physiological data displayed by the master interface.
2. The method of claim 1, wherein the editing gesture comprises a touch point and a touch direction, and wherein determining the type and direction of interface switching according to the editing gesture comprises:

   acquiring the number of touch points included in the editing gesture;

   if the number of the touch points is larger than a preset threshold value, determining that the type of the interface switching is a main interface switching type, and determining the touch direction as a main interface switching direction;

   and if the number of the touch points is smaller than or equal to a preset threshold value, determining that the type of the interface switching is a slave interface switching type, and determining the touch direction as a slave interface switching direction.
3. The method according to claim 2, wherein switching the currently displayed interface according to the interface switching direction according to the type of the interface switching comprises:

   if the interface switching type is a main interface switching type, determining a first main interface corresponding to the current display interface;

   acquiring a second main interface according to the main interface switching direction;

   and switching the current display interface to the second main interface.
4. The method according to claim 2, wherein the switching the currently displayed interface according to the type of the interface switching and the direction of the interface switching comprises:

   if the type of the interface switching is a slave interface switching type, acquiring a target slave interface according to the slave interface switching direction;

   and switching the current display interface into the target slave interface.
5. The method of claim 1,

   the main interface includes: a large digital interface and/or a waveform interface; the slave interface is subordinate to the master interface and comprises any one or more of a state trend interface, a grading detail interface and a grading history interface.
6. The method of claim 3 or 4, wherein the currently displayed interface includes at least one shortcut control for controlling the corresponding interface, further comprising:

   and if the click operation of the user on the shortcut control is received, switching the current display interface to the interface corresponding to the shortcut control.
7. The method according to claim 1, wherein the determining of the type and direction of interface switching according to the editing gesture, and the switching processing of the current display interface according to the direction of interface switching according to the type of interface switching at least comprises one of the following steps:

   expanding any one or more of a state trend interface, a scoring detail interface and a scoring history interface from the edge of the main interface according to the editing gesture;

   expanding a scoring interface from the edge of the main interface along a first direction according to the editing gesture;

   deploying a scoring detail interface from the scoring interface in a second direction according to the editing gesture;

   expanding a state trend interface from the scoring interface or the scoring detail interface along a third direction according to the editing gesture;

   expanding a scoring history interface in a second direction from the scoring interface or scoring detail interface according to the editing gesture;

   and sequentially unfolding the short-time trend change chart and the long-time trend change chart in the state trend interface along the third direction along with the sliding of the editing gesture on the display interface.
8. The method of claim 7, wherein the third direction and the second direction are different.
9. A monitoring device, comprising: a data interface, a processor, a memory, said data interface, processor and memory being interconnected, wherein,

   the memory for storing a computer program comprising program instructions, the processor configured to invoke the program instructions, perform the steps of:

   acquiring at least one physiological parameter signal in a first time period through a sensor accessory connected with a patient, and generating parameter data containing at least one physiological parameter according to the acquired at least one physiological parameter signal;

   displaying parameter data of the at least one physiological parameter;

   receiving the editing operation of a user on the current display interface of the monitoring equipment;

   acquiring an editing gesture corresponding to the editing operation;

   determining the type and the direction of interface switching according to the editing gesture, wherein the type of interface switching comprises the following steps: a master interface switching type or a slave interface switching type;

   according to the type of the interface switching, switching the current display interface according to the direction of the interface switching,

   wherein, the slave interface comprises a statistical analysis result based on the physiological data displayed by the master interface.
10. The apparatus of claim 9, wherein the processor is further configured to perform the steps of:

    acquiring the number of touch points included in the editing gesture;

    if the number of the touch points is larger than a preset threshold value, determining that the type of the interface switching is a main interface switching type, and determining the touch direction as a main interface switching direction;

    and if the number of the touch points is smaller than or equal to a preset threshold value, determining that the type of the interface switching is a slave interface switching type, and determining the touch direction as a slave interface switching direction.
11. The apparatus of claim 10, wherein the processor is further configured to perform the steps of:

    if the interface switching type is a main interface switching type, determining a first main interface corresponding to the current display interface;

    acquiring a second main interface according to the main interface switching direction;

    and switching the current display interface to the second main interface.
12. The apparatus of claim 10, wherein the processor is further configured to perform the steps of:

    if the type of the interface switching is a slave interface switching type, acquiring a target slave interface according to the slave interface switching direction;

    and switching the current display interface into the target slave interface.
13. The apparatus of claim 9,

    the main interface includes: a large digital interface and/or a waveform interface; the slave interface is subordinate to the master interface and comprises any one or more of a state trend interface, a grading detail interface and a grading history interface.
14. The apparatus of claim 11 or 12, wherein the processor is further configured to perform the steps of:

    and if the click operation of the user on the shortcut control is received, switching the current display interface to the interface corresponding to the shortcut control.
15. The device according to claim 9, wherein the processor determines a type and a direction of interface switching according to the editing gesture, and performs at least one of the following steps when switching the currently displayed interface according to the direction of interface switching according to the type of interface switching:

    expanding any one or more of a state trend interface, a scoring detail interface and a scoring history interface from the edge of the main interface according to the editing gesture;

    expanding a scoring interface from the edge of the main interface along a first direction according to the editing gesture;

    deploying a scoring detail interface from the scoring interface in a second direction according to the editing gesture;

    expanding a state trend interface from the scoring interface or the scoring detail interface along a third direction according to the editing gesture;

    expanding a scoring history interface in a second direction from the scoring interface or scoring detail interface according to the editing gesture;

    and sequentially unfolding the short-time trend change chart and the long-time trend change chart in the state trend interface along the third direction along with the sliding of the editing gesture on the display interface.
16. The apparatus of claim 15, wherein the third direction and the second direction are different.
17. An interface operation method applied to a monitoring device is characterized by comprising the following steps:

    acquiring at least one physiological parameter signal in a first time period through a sensor accessory connected with a patient, and generating a real-time waveform and/or a real-time numerical value containing at least one physiological parameter according to the acquired at least one physiological parameter signal;

    displaying the real-time waveform and/or real-time numerical value of the at least one physiological parameter on a display interface;

    receiving the editing operation of a user on the current display interface of the monitoring equipment;

    acquiring an editing gesture corresponding to the editing operation;

    determining a switching direction according to the editing gesture;

    and displaying a slave interface expansion on the display interface along the switching direction, wherein the slave interface comprises a statistical analysis result based on the real-time waveform and/or the real-time numerical value.
18. The device of claim 17, wherein the slave interface comprises any one or more of a state trend interface, a scoring detail interface, and a scoring history interface.
19. The apparatus of claim 17, wherein the displaying the slave interface spread in the switching direction on the display interface comprises at least one of:

    expanding a scoring interface from an edge of the display interface along a first direction;

    expanding a scoring detail interface along a second direction;

    expanding the state trend interface along a third direction;

    expanding a grading history interface along a second direction; and the combination of (a) and (b),

    and sequentially unfolding the short-time trend change chart and the long-time trend change chart in the state trend interface along the third direction along with the sliding of the editing gesture on the display interface.
20. The device of claim 17, wherein the editing gesture is a swipe operation.
21. The apparatus of claim 19, wherein the third direction is perpendicular to the second direction or the first direction.
22. A monitoring device, characterized in that the monitoring device comprises:

    a parameter measurement circuit electrically connected to a sensor accessory disposed on a patient's body for obtaining at least one physiological parameter signal;

    a processor and a memory;

    the memory is used for storing computer programs, and the processor is used for implementing the following steps when executing the computer programs stored in the memory:

    generating a real-time waveform and/or a real-time numerical value containing at least one physiological parameter according to the obtained at least one physiological parameter signal;

    displaying the real-time waveform and/or real-time numerical value of the at least one physiological parameter on a display interface;

    receiving the editing operation of a user on the current display interface of the monitoring equipment;

    acquiring an editing gesture corresponding to the editing operation;

    determining a switching direction according to the editing gesture;

    and displaying a slave interface expansion on the display interface along the switching direction, wherein the slave interface comprises a statistical analysis result based on the real-time waveform and/or the real-time numerical value.
23. The device of claim 22, wherein the slave interface comprises any one or more of a state trend interface, a scoring detail interface, and a scoring history interface.
24. The device of claim 22, wherein the processor is configured to cause the display of the slave interface spread in the switch direction on the display interface by at least one of:

    expanding a scoring interface from an edge of the display interface along a first direction;

    expanding a scoring detail interface along a second direction;

    expanding the state trend interface along a third direction;

    expanding a grading history interface along a second direction; and the combination of (a) and (b),

    and sequentially unfolding the short-time trend change chart and the long-time trend change chart in the state trend interface along the third direction along with the sliding of the editing gesture on the display interface.
25. The device of claim 22, wherein the editing gesture is a swipe operation.
26. The apparatus of claim 24, wherein the third direction is perpendicular to the second direction or the first direction.

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