CN114816380B

CN114816380B - Low-code platform for medical institution

Info

Publication number: CN114816380B
Application number: CN202210387720.2A
Authority: CN
Inventors: 吴笛
Original assignee: Hubei Fuxin Kechuang Information Technology Co ltd
Current assignee: Hubei Fuxin Kechuang Information Technology Co ltd
Priority date: 2022-04-13
Filing date: 2022-04-13
Publication date: 2022-10-11
Anticipated expiration: 2042-04-13
Also published as: CN114816380A

Abstract

The invention relates to the technical field of low-code platforms, and discloses a low-code platform for a medical institution, which comprises a bounded surface display unit, a creating operation detection unit, a creating operation response unit, a dragging operation detection unit, a dragging operation response unit, a selected operation detection unit, a selected operation response unit, an editing operation detection unit, an editing operation response unit, a generating operation detection unit and a generating operation response unit, and can respond to page creating operation, component dragging operation and component selecting operation of a medical institution user and component editing operation for node editing and/or connection relation editing of a graphical process network for realizing a medical information processing function, so that the medical institution user lacking I T knowledge can directly develop and build medical service software meeting personalized requirements, further entrustment development and requirement handover are not needed, development speed is effectively accelerated, development period is shortened, development cost is reduced, and development satisfaction degree can be guaranteed.

Description

Low-code platform for medical institution

Technical Field

The invention belongs to the technical field of low-code platforms, and particularly relates to a low-code platform for medical institutions.

Background

In recent years, with the rapid development of the technology level of the software industry, many enterprises have realized the digital online capability, and more enterprises rely on business software to perform intelligent management on companies. Because different enterprises have different requirements, platform providers are born in order to meet more personalized and customized client requirements more conveniently when facing so many industrial clients.

The low-code platform is a digital technology tool platform which can rapidly realize innovation application in enterprise digital transformation in a graphical and dragging mode and can support the realization of personalized requirements by using a small amount of code expansion, is a capability platform for business personnel and IT personnel to bidirectionally drive and manage, has the visual configuration capability of a general scene, meets the realization of the operation innovation scene requirements, has excellent openness and expansibility, can realize various personalized scene requirements during enterprise planning and design through secondary development, and is not limited to code development, plug-in expansion, social plug-in citation and the like. Therefore, the low-code platform has the characteristics of low technical threshold, short delivery cycle, high development efficiency, quickness in innovation and the like, can help enterprises to quickly realize 'service digitization' to 'digital service' in digital transformation, completely accords with scene, flattening and online of the trend of digital transformation, and is an indispensable digital technical tool platform in digital transformation.

Currently, a low-code platform has corresponding development products for many industrial customers, for example, a patent CN111897528 a-a low-code platform for enterprise online education "provides an educational software development tool for educational industrial customers, but a corresponding applicable product is still lacking for medical institutions. Because the major industry of medical institution users is treating and saving people and providing health services for the people, but IT is unknown to the IT knowledge required by software development, software practitioners are generally entrusted to help develop own medical service software, so that the requirements need to be handed over repeatedly, and the problems of low development speed, long development period and high development cost exist.

Disclosure of Invention

In order to solve the problems of low development speed, long development period and high development cost of the conventional medical service software, the invention aims to provide a low-code platform for a medical institution, so that a medical institution user lacking IT knowledge can directly develop and build the medical service software meeting individual requirements, further development and requirement handover do not need to be entrusted, the development speed is effectively increased, the development period is shortened, the development satisfaction is reduced, and the practical application and popularization are facilitated.

In a first aspect, the present invention provides a low code platform for medical institutions, which is used as a medical software generation tool and includes an interface display unit, a creation operation detection unit, a creation operation response unit, a drag operation detection unit, a drag operation response unit, a selected operation detection unit, a selected operation response unit, an editing operation detection unit, an editing operation response unit, a generation operation detection unit, and a generation operation response unit:

the interface display unit is used for displaying a human-computer interaction interface of the medical software generation tool to a medical institution user;

the creation operation detection unit is in communication connection with the interface display unit and is used for detecting whether page creation operation occurs on the human-computer interaction interface or not, wherein the page creation operation refers to human-computer interaction operation of a medical institution user triggering a page creation instruction on the human-computer interaction interface;

the creating operation response unit is respectively in communication connection with the creating operation detection unit and the interface display unit, and is used for creating a new page in a page bar on the human-computer interaction interface and displaying an assembly model bar and a page editing window of the new page on the human-computer interaction interface when detecting that the page creating operation has occurred, wherein the assembly model bar is provided with a plurality of functional assembly models for realizing different medical information processing functions;

the dragging operation detection unit is in communication connection with the interface display unit and is used for detecting whether a first component dragging operation occurs on the human-computer interaction interface, wherein the first component dragging operation refers to a human-computer interaction operation of dragging a certain functional component model from the component model bar into the page editing window by the medical institution user;

the dragging operation response unit is respectively in communication connection with the dragging operation detection unit and the interface display unit and is used for placing a new functional component generated based on the certain functional component model in the page editing window according to a dragging result of the dragging operation of the first component when the dragging operation of the first component is detected to occur;

the selected operation detection unit is in communication connection with the interface display unit and is used for detecting whether a first component selected operation occurs on the human-computer interaction interface, wherein the first component selected operation refers to a human-computer interaction operation of the medical institution user for selecting a certain functional component in the page editing window;

the selected operation response unit is respectively in communication connection with the selected operation detection unit and the interface display unit, and is configured to display a graphical editing window of the certain functional component on the human-computer interaction interface when it is detected that the first component selected operation has occurred, where the graphical editing window displays a graphical process network that is of the certain functional component and is pre-templated, the graphical process network includes a plurality of graphical process nodes and connection relationships between node ports, the graphical process node is an encapsulation module that is formed by predefined semantics and a visual graph, the predefined semantics includes node attribute information, port attribute information and a modular subprogram, the visual graph integrates a node name, a port name, a node block graph corresponding to the node attribute information and a port graph corresponding to the port attribute information, the node type of the graphical process node includes an input type node, an output type node, a numerical type node, a variable type node, an expression type node, a control process type node, a function type node, a method type node, an execution type node and/or an event type node, the node type of the graphical process node includes at least one graphical input port and/or at least one graphical process type node, and the graphical process type node includes at least one graphical process type node;

the editing operation detection unit is in communication connection with the interface display unit and is used for detecting whether a first component editing operation has occurred on the human-computer interaction interface, wherein the first component editing operation refers to a human-computer interaction operation of node editing and/or connection relation editing of the graphical process network in the graphical editing window by the medical institution user;

the editing operation response unit is respectively in communication connection with the editing operation detection unit and the interface display unit, and is used for updating and storing the graphical flow network of the certain functional component according to the editing result of the editing operation of the first component when the editing operation of the first component is detected to occur;

the generation operation detection unit is in communication connection with the interface display unit and is used for detecting whether software generation operation has occurred on the human-computer interaction interface, wherein the software generation operation refers to human-computer interaction operation that the medical institution user selects at least one page in the page column and triggers a software generation instruction on the human-computer interaction interface;

the generation operation response unit is in communication connection with the generation operation detection unit and is used for generating medical service software according to the editing result of each page in the at least one page when the software generation operation is detected to occur.

Based on the content of the invention, a medical software generation tool for generating personalized medical service software by responding to human-computer interaction operation of a medical institution user is provided, and the medical software generation tool comprises a bounded surface display unit, a creation operation detection unit, a creation operation response unit, a dragging operation detection unit, a dragging operation response unit, a selected operation detection unit, a selected operation response unit, an editing operation detection unit, an editing operation response unit, a generation operation detection unit and a generation operation response unit, and can respond to page creation operation, component dragging operation, component selection operation of a medical institution user, and component editing operation for node editing and/or connection relation editing of a graphical process network for realizing a medical information processing function, and finally automatically generate the medical service software according to an editing result of each page in at least one selected page based on software generation operation.

In one possible design, the functional component models include an economic management functional component model, a drug management functional component model, a clinic diagnosis functional component model, a statistical analysis functional component model and/or an external interface functional component model, wherein the economic management functional component model includes an emergency registration component model, an emergency pricing component model, an entrance and exit management component model and/or an in-hospital charging component model, the drug management functional component model includes a drug library management component model, an outpatient pharmacy management component model, an in-hospital pharmacy management component model and/or a drug price management component model, the clinic diagnosis functional component model includes an outpatient doctor workstation component model and/or a nurse workstation component model, the statistical analysis functional component model includes a medical statistics component model, a hospital length comprehensive query and analysis component model and/or a health bureau comprehensive query and analysis component model, and the external interface functional component model includes a medical insurance system interface component model, a bidirectional diagnosis system interface component model, a remote medical consultation system interface component model and/or a health care system interface model.

In one possible design, when the page creation instruction includes a specified target, displaying a page editing window of the new page on the human-computer interaction interface, including: and displaying a page editing window of the new page on the man-machine interaction interface, wherein the page editing window is matched with a display screen of the target terminal, and the target terminal is a smart phone terminal or a Personal Computer (PC) terminal.

In one possible design, when the page creation command includes a specified page type, creating a new page in a page column on the human-computer interaction interface, including:

displaying a plurality of page models corresponding to the page types on the human-computer interaction interface, wherein the page types are software main pages or software sub-pages, a pre-templated functional component set is placed in a page editing window of each page model, and each functional component set comprises at least one functional component model;

and creating a new page which is the same as the selected page model in a page bar on the human-computer interaction interface according to a selection result of the medical institution user on the plurality of page models.

In one possible design, displaying a plurality of page models corresponding to the page types on the human-computer interaction interface includes:

acquiring a plurality of page models corresponding to the page types, wherein the page types are software main pages or software sub-pages, a pre-templated functional component set is placed in a page editing window of each page model, and the functional component set comprises at least one functional component model;

calculating the similarity between the corresponding page image and an established page image aiming at each page model in the plurality of page models to obtain the corresponding image similarity, wherein the established page image refers to the page images of a plurality of previous pages which are arranged in a page column on the human-computer interaction interface according to the creation time in a descending order;

and displaying the plurality of page models on the human-computer interaction interface in a carousel mode according to the sequence of the similarity of the images from large to small.

In one possible design, the component model column is further provided with a plurality of different tab component models;

the dragging operation detection unit is further configured to detect whether a second component dragging operation has occurred on the human-computer interaction interface, where the second component dragging operation refers to a human-computer interaction operation in which the medical institution user drags a certain label component model from the component model bar and enters the page editing window;

the drag operation response unit is further configured to, when it is detected that the second component drag operation has occurred, place, in the page editing window, a new tag component generated based on the certain tag component model according to a drag result of the second component drag operation;

the selected operation detection unit is further configured to detect whether a second component selected operation has occurred on the human-computer interaction interface, where the second component selected operation is a human-computer interaction operation in which the medical institution user selects a certain tag component in the page editing window;

the selected operation response unit is further configured to, when it is detected that the second component selected operation has occurred, display a component property editing window of the certain tag component on the human-computer interaction interface, where the component property editing window presents editable property information of the certain tag component, and the editable property information includes a diagram position, a diagram shape, a diagram size, and/or a diagram content of the certain tag component in the located page;

the editing operation detection unit is further configured to detect whether a second component editing operation has occurred on the human-computer interaction interface, where the second component editing operation is a human-computer interaction operation performed by the medical institution user for editing the editable attribute information in the component attribute editing window;

and the editing operation response unit is further configured to, when it is detected that the second component editing operation has occurred, update and store the editable attribute information of the certain tag component according to an editing result of the second component editing operation.

In one possible design, the editable attribute information further includes a hyperlink address for triggering access after clicking the illustration content or a sub-page unique identifier for triggering switching and loading of a certain software sub-page, where the certain software sub-page is a created page in the page column.

In one possible design, node editing is performed on the graphical process network in the graphical editing window, and the node editing includes:

adding a first new graphical process node with a node type of an input node in the graphical editing window, and designating the first new graphical process node as a graphical process node in a graphical process network of another functional component, wherein the node type of the graphical process node is an output node;

and/or adding a second new graphical process node with the node type as an output type node in the graphical editing window, so that the second new graphical process node is specified as a graphical process node in a graphical process network of another functional component, wherein the node type is an input type node.

In one possible design, updating the graphical process network that stores the certain functional component according to the editing result of the editing operation of the first component includes:

sequentially running subprograms of all graphical process nodes in the graphical editing window based on the data flow direction and/or the execution direction determined by the connection relation between the ports according to the editing result of the first component editing operation;

if a certain graphical process node in all the graphical process nodes has an operation error, stopping the operation, and identifying a node block graph of the certain graphical process node in an error reporting state color in the graphical editing window;

and if the operation errors do not occur in all the graphical process nodes, updating and storing the graphical process network of the certain functional component.

In one possible design, when the software generation instruction includes a specified target system, generating medical service software according to an editing result of each page in the at least one page, including:

and generating medical service software corresponding to the target system according to the editing result of each page in the at least one page, wherein the target system is a hongmeng system, a Windows system, a Linux system, an Android system or an ios system.

Drawings

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

Fig. 1 is a schematic structural diagram of a low-code platform for medical institutions provided by the invention.

FIG. 2 is an exemplary diagram of a human-machine interface of a medical software generation tool provided by the present invention.

FIG. 3 is a graphical illustration of a visualization of a graphical process node provided by the present invention.

FIG. 4 is an exemplary diagram of a graphical process network provided by the present invention.

Detailed Description

The invention is further described with reference to the following figures and specific embodiments. It should be noted that the description of the embodiments is provided to help understanding of the present invention, but the present invention is not limited thereto. Specific structural and functional details disclosed herein are merely representative of exemplary embodiments of the invention. This invention may, however, be embodied in many alternate forms and should not be construed as limited to the embodiments set forth herein.

It will be understood that, although the terms first, second, etc. may be used herein to describe various objects, these objects should not be limited by these terms. These terms are only used to distinguish one object from another. For example, a first object may be referred to as a second object, and similarly, a second object may be referred to as a first object, without departing from the scope of example embodiments of the present invention.

It should be understood that, for the term "and/or" as may appear herein, it is merely an associative relationship that describes an associated object, meaning that three relationships may exist, e.g., a and/or B may mean: a exists alone, B exists alone or A and B exist at the same time; for the term "/and" as may appear herein, which describes another associative object relationship, it means that two relationships may exist, e.g., a/and B, may mean: a exists singly or A and B exist simultaneously; in addition, for the character "/" that may appear herein, it generally means that the former and latter associated objects are in an "or" relationship.

As shown in fig. 1, the low-code platform for medical institutions provided in the first aspect of this embodiment is used as a medical software generation tool, and is required to be installed on a Computer device with certain computing resources, for example, a Personal Computer (PC, which refers to a multipurpose Computer with a size, price, and performance suitable for Personal use, and electronic devices such as a desktop Computer, a notebook Computer, a small notebook Computer, a tablet Computer, a super Computer, and the like, all belong to a Personal Computer), a smart phone, a Personal digital assistant (PAD), or a wearable device, so as to respond to human-Computer interaction operations of users, so that a medical institution user lacking in IT knowledge can directly develop and build medical service software meeting personalized requirements, and further, development and requirement handover are not required, so as to effectively accelerate development speed, shorten development period, reduce development cost, and ensure development satisfaction, and facilitate practical application and popularization.

The low-code platform is used as a medical software generation tool and comprises but is not limited to an interface display unit, a creation operation detection unit, a creation operation response unit, a dragging operation detection unit, a dragging operation response unit, a selected operation detection unit, a selected operation response unit, an editing operation detection unit, an editing operation response unit, a generation operation detection unit, a generation operation response unit and the like, wherein the interface display unit is used for displaying a human-computer interaction interface of the medical software generation tool for a medical institution user.

The creation operation detection unit is in communication connection with the interface display unit and is used for detecting whether page creation operation has occurred on the human-computer interaction interface, wherein the page creation operation refers to human-computer interaction operation in which a page creation instruction is triggered by a user of the medical institution on the human-computer interaction interface. As shown in fig. 2, for example, a "new" button is preset in the upper left dashed box area of the human-computer interaction interface, and the page creation instruction may be triggered by clicking the "new" button. The specific action mode of detection is preferably realized through a View layer in a Model-View-Controller (MVC) architecture (which is an existing software architecture for realizing separation of service logic, data and interface display and sequentially comprises a View layer, a control layer and a Model layer from top to bottom) (namely, the Model-View-Controller MVC architecture is adopted by the custom page generation tool), so that after human-computer interaction operation is detected, the human-computer interaction operation can be transmitted to the Model layer through the control layer, and finally, the operation is responded in the Model layer, so that the characteristic of separating the service logic, the data and the interface display can be realized based on the MVC architecture, when a medical institution user initiates the human-computer interaction operation through the human-computer interaction mode, only simple operation is required to be performed on a control interface provided by the View layer, the service logic does not need to be rewritten, the medical institution user is greatly facilitated to perform the human-computer interaction, and the user experience is improved.

The creation operation response unit is respectively in communication connection with the creation operation detection unit and the interface display unit, and is configured to create a new page in a page bar on the human-computer interaction interface and display an assembly model bar and a page editing window of the new page on the human-computer interaction interface when it is detected that the page creation operation has occurred, where the assembly model bar is provided with a plurality of functional assembly models for implementing different medical information processing functions. As shown in fig. 2, for example, the page column is located at the left side of the human-computer interaction interface and is used for listing all the created pages (limited to the display area, and each page can be displayed in a carousel manner by mouse scrolling/pulling); the component model column is positioned at the upper right side of the human-computer interaction interface and used for listing the functional component models which are designed in advance so as to facilitate dragging and adding (the component models are also limited to a display area, and each functional component model can be displayed in a carousel mode in a mouse rolling/pulling mode); the page editing window is positioned in the middle area of the man-machine interaction interface and used for providing an editing operation area of a page and previewing the page in a visible and ready-to-obtain mode. In addition, the functional component models include, but are not limited to, an economic management functional component model, a drug management functional component model, a clinical diagnosis functional component model, a statistical analysis functional component model, and/or an external interface functional component model, wherein the economic management functional component model includes, but is not limited to, an outpatient service registration component model, an outpatient service pricing component model, an entrance and exit management component model, and/or an in-patient charging component model, the drug management functional component model includes, but is not limited to, a pharmacy management component model, an in-patient pharmacy management component model, and/or a drug price management component model, the clinical diagnosis functional component model includes, but is not limited to, an outpatient workstation component model, and/or a nurse workstation component model, the statistical analysis functional component model includes, but is not limited to, a medical statistics component model, a hospital comprehensive query and analysis component model, and/or a health bureau comprehensive query and analysis component model, and the external interface functional component model includes, but is not limited to, a medical insurance system interface component model, a two-way medical system interface component model, a remote medical consultation system interface component model, and/or a maternal care system interface model. The functional component models can be obtained by conventional programming in advance based on the corresponding medical information processing mode.

Preferably, when the page creation instruction includes a specified target end, a page editing window of the new page is displayed on the human-computer interaction interface, including but not limited to: and displaying a page editing window of the new page on the man-machine interaction interface, wherein the page editing window is matched with a display screen of the target terminal, and the target terminal is a smart phone terminal or a Personal Computer (PC) terminal. As shown in fig. 2, for example, a "mobile phone end" selection button and a "PC" end selection button are preset in the area of the dashed line frame on the upper left side of the human-computer interaction interface, and the target end may be specified by clicking the "mobile phone end" selection button or the "PC" end selection button. Because the display screen of the smart phone end is a vertical screen and the display screen of the PC end is a horizontal screen, if medical service software suitable for running on the smart phone end or the PC end is to be generated, a target end needs to be specified in advance, and a software page suitable for being displayed on the target end is obtained by providing a page editing window matched with the display screen of the target end.

The dragging operation detection unit is in communication connection with the interface display unit and is used for detecting whether a first component dragging operation occurs on the human-computer interaction interface, wherein the first component dragging operation refers to a human-computer interaction operation of dragging a certain functional component model from the component model bar into the page editing window by the medical institution user. The certain functional component model represents the functional components that the medical institution user wants to add in the page, so as to provide the corresponding medical information processing function in the page, for example, providing an outpatient emergency registration function and the like.

The drag operation response unit is respectively in communication connection with the drag operation detection unit and the interface display unit, and is configured to place, when it is detected that the first component drag operation has occurred, a new functional component generated based on the certain functional component model in the page editing window according to a drag result of the first component drag operation. The new functional component is a content element which the medical institution user wants to add in the page, and the generation mode of the new functional component can be automatically generated based on the preset template content of the certain functional component model. Specifically, according to the dragging result of the dragging operation of the first component, a new functional component generated based on the certain functional component model is placed in the page editing window, including but not limited to: and acquiring a dragging terminal of the certain functional component model in the page editing window according to a dragging result of the first component dragging operation, and then placing a new functional component generated based on the certain functional component model at the dragging terminal.

The selected operation detection unit is in communication connection with the interface display unit and is used for detecting whether a first component selected operation occurs on the human-computer interaction interface, wherein the first component selected operation refers to a human-computer interaction operation of the medical institution user selecting a certain functional component in the page editing window. Specifically, the certain functional component may be selected from at least one functional component located in the page editing window by a conventional man-machine input manner, such as a mouse operation or a touch screen operation.

The selected operation response unit is respectively in communication connection with the selected operation detection unit and the interface display unit, and is configured to display a graphical editing window of the certain functional component on the human-computer interaction interface when it is detected that the first component selected operation has occurred, where the graphical editing window displays a graphical process network that is of the certain functional component and is pre-templated, the graphical process network includes, but is not limited to, a plurality of graphical process nodes and connection relationships between node ports, the graphical process nodes are encapsulation modules that are formed by predefined semantics and visual graphs, the predefined semantics include, but is not limited to, node attribute information, port attribute information and modular subroutines, the visual graphs integrate, but not limited to, node names, port names, node block graphs corresponding to the node attribute information, and port graphs corresponding to the port attribute information, the node types of the graphical process nodes include, but are not limited to, input type nodes, output type nodes, numerical type nodes, variable type nodes, expression type nodes, process control type nodes, function type nodes, method type nodes, execution type nodes, event type nodes, or event type nodes, and/or the like, and the graphical process nodes include, and/or graphical process nodes including, and/or graphical input ports. As shown in fig. 2, for example, the graphical editing window is located at the lower right side of the human-computer interaction interface and is used for providing an editing operation area of a functional component and presenting medical information processing logic to the medical institution user in a graphical flow network manner (not in a code manner). As shown in fig. 3, the graphical process node may, but is not limited to, be modularly packaged in a json file format, where the predefined semantics are defined in advance by an existing special semantics editor and are used for dynamically generating a node sample, controlling data, performing operations, and the like, where the node attribute information, the port attribute information, and the sub-program need to be template-customized in advance to implement a specific type function of a corresponding node. The visualization graph is used for representing the corresponding graphical process nodes in the graphical editing window, wherein the node block graph can be but is not limited to a square, a circle, a triangle or a regular polygon, and the port graph can also be but is not limited to a square, a circle, a triangle or a regular polygon. In addition, a node of a graphical process has at least one output port or one input port, for example, in a json file, the output port of a node may be defined first, and then the input port of the node may be defined. Therefore, the graphical process network can form a program file to realize the corresponding medical information processing function through the connection relationship among a plurality of graphical process nodes and node ports, as shown in fig. 4.

Specifically, the node attribute information may include, but is not limited to, contents such as a node ID, a node package name, a node author, a node name, a node type, and/or a support language. And the node ID is used for uniquely identifying the corresponding graphical process node so as to facilitate quick search. The node package names are used to organize an index of the categorized node series. The node type is used for identifying a specific type of the corresponding graphical process node, for example, identifying the node as an input type node which is used for outputting data from the outside and therefore only has an output port; identified as output type nodes-which are used to output data to the outside, and therefore have only input ports; identified as a data-type node-which is used to output data in a particular format, such as numerical values, character strings, etc., and which is customizable; identified as a variable-type node-which is used to output variables and can also be custom edited; identified as an expression type node-it is used to output expressions, not customizable; identified as flow control type nodes for performing data operations in a preset logical order, such as flow control logic based on if conditional statements or for/while loop statements, etc.; identified as a functional node for performing data operations according to a preset function; identified as a method type node for performing data operations according to a preset method; identified as executing nodes, which are used for final encoding and execution, there must be at least one executing node in one program file; identified as an event type node, which is used to provide pre-call conditions prior to program execution, such as: when a certain event such as a certain key of a keyboard is pressed, a node network under a certain executive node is called to start execution, and the node is not required by each program file. The node type may affect the visual display effect of the corresponding node — that is, in the graphical editing window, the node block graphs of various node types may be identified in a one-to-one correspondence with different first preset patterns, where the first preset patterns may include, but are not limited to, shapes and/or colors, for example, a numerical node is identified by a preset color with a color hexadecimal of 9ABC66, and a variable node is identified by a preset color with a color hexadecimal of 77AFD 9.

Specifically, the port attribute information may include, but is not limited to, port ID, port name, connection necessity, port data type, port interaction type, port external command and/or expression, and the like. The port ID is used to uniquely identify a corresponding port, and in a default case, the visual port belongs to a default port group, such as an above 0, igrioup0. The connection necessity is used for identifying whether a corresponding port is an essential connection characteristic in a programming process by adopting a true state and a false state (namely 1 or 0), which also affects the visual display effect of the node, namely in a graphical editing window, if a port without a connection relation exists in all essential connection ports (namely the connection necessity of the port is 1, which represents the essential connection characteristic), the graphical process node is identified by an error-reporting state preset color (for example, positive red), so that a programmer can quickly find a node which is possible to make an error. The port data type is used to identify a data transmission type of a corresponding port, which may include, but is not limited to, a numeric port (which is used to transmit numeric data between nodes), a boolean port (which is used to transmit boolean data between nodes), a string port (which is used to transmit string data between nodes), a list port (which is used to transmit list data between nodes), a tuple port (which is used to transmit tuple data between nodes), a dictionary port (which is used to transmit dictionary data between nodes), an aggregate port (which is used to transmit aggregate data between nodes), a file port (which is used to transmit file data between nodes), a full-state port (which is used to transmit data of all different data types between nodes), an executive port (which is used to transmit executive command data between nodes), and/or a virtual port (which is a port to be edited that allows for dynamic port visualization, which may be identified by open circles in an example), etc. The port data type also affects the visual display effect of the corresponding port, that is, in the graphical editing window, the port graphics of various port data types are identified in a one-to-one correspondence manner in different second preset patterns, wherein the second preset patterns may include, but are not limited to, shapes and/or colors, for example, a digital port is identified by a preset color with a green color, and a typical port is identified by a preset color with a positive blue color; and identifying some ports by different graphical shapes, such as identifying executive ports with squares, virtual ports with open circles, for solid circles to identify other types of ports.

The editing operation detection unit is in communication connection with the interface display unit and is used for detecting whether a first component editing operation has occurred on the human-computer interaction interface, wherein the first component editing operation refers to a human-computer interaction operation of the medical institution user performing node editing and/or connection relation editing on the graphical process network in the graphical editing window. The node editing includes, but is not limited to, adding a node, deleting a node, or changing a predefined semantic meaning of a node (considering that IT knowledge of a medical institution user is limited, this editing operation will be few but not prohibited), and the like, and the connection relationship editing includes, but is not limited to, establishing a connection relationship, deleting a connection relationship, or changing a connection relationship, and the like. Preferably, in order to import data of other functional components, node editing is performed on the graphical process network in the graphical editing window, including but not limited to: and adding a first new graphical process node with the node type of an input node in the graphical editing window, designating the first new graphical process node as a graphical process node in a graphical process network of another functional component with the node type of an output node, and establishing a connection relationship between the first new graphical process node and other graphical process nodes to achieve the purpose of importing data by application. And node editing the graphical flow network in the graphical editing window in order to be able to export data to other functional components, including but not limited to: and adding a second new graphical process node with the node type as an output type node in the graphical editing window so that the second new graphical process node is specified as a graphical process node in a graphical process network of another functional component and the node type is an input type node, and then establishing the connection relationship between the second new graphical process node and other graphical process nodes to achieve the purpose of exporting data. In addition, in the process of editing the connection relationship, in order to prevent syntax errors from occurring in advance, it is preferable that if the two port data types respectively corresponding to the output port graph and the input port graph are found to be mismatched, the establishment of the connection relationship between the ports is terminated.

The editing operation response unit is respectively in communication connection with the editing operation detection unit and the interface display unit, and is used for updating and storing the graphical flow network of a certain functional component according to an editing result of the editing operation of the first component when the editing operation of the first component is detected to occur. Preferably, in order to implement the purpose of timely debugging the graphical process network, the graphical process network for storing the certain functional component is updated according to the editing result of the editing operation of the first component, which includes but is not limited to: sequentially running subprograms of all graphical process nodes in the graphical editing window on the basis of the data flow direction and/or the execution direction determined by the connection relation between ports according to the editing result of the first component editing operation; if a certain graphical process node in all the graphical process nodes has an operation error, stopping the operation, and identifying a node block graph of the certain graphical process node in an error reporting state color in the graphical editing window; and if the operation errors do not occur in all the graphical process nodes, updating and storing the graphical process network of the certain functional component. Therefore, by the error reporting mode, the graphical process node with the error can be quickly found out so as to be corrected in time, and the program file based on the graphical process network can be ensured to run normally, thereby realizing the corresponding medical information processing function.

The generation operation detection unit is in communication connection with the interface display unit and is used for detecting whether software generation operation has occurred on the human-computer interaction interface, wherein the software generation operation refers to human-computer interaction operation that the medical institution user selects at least one page in the page column and triggers a software generation instruction on the human-computer interaction interface. As shown in fig. 2, for example, a "create" button is preset in a lower dashed box area of the human-computer interaction interface, and after at least one page is selected in the page column (for example, "page 1", "page 2", "page 3", and "new page" are selected), the "create" button is clicked to trigger the software generation instruction. Furthermore, the at least one page needs to contain one page for being a main page of the software and/or at least one page for being a sub-page of the software.

The generation operation response unit is in communication connection with the generation operation detection unit and is used for generating medical service software according to the editing result of each page in the at least one page when the software generation operation is detected to occur. Since the at least one page has at least one functional component after editing, the healthcare service software having at least one healthcare information processing function can be generated by a conventional page combination manner.

Preferably, when the software generation instruction includes a specified target system, the medical service software is generated according to the editing result of each page in the at least one page, including but not limited to: and generating medical service software corresponding to the target system according to the editing result of each page in the at least one page, wherein the target system can be but is not limited to a Hongmon system, a Windows system, a Linux system, an Android system, an ios system and the like. As shown in fig. 2, for example, a "hongmeng" selection button, a "Windows" selection button, a "Linux" selection button, an "Android" selection button, an "ios" selection button, and the like are preset in a lower dotted frame area of the human-computer interaction interface, and the target system can be specified by clicking one of the selection buttons, so that medical service software suitable for the hongmeng system, the Windows system, the Linux system, the Android system, the ios system, and the like can be generated by one key, and user experience is improved.

Therefore, based on the low-code platform facing the medical institution, a medical software generation tool for generating personalized medical service software by responding to human-computer interaction operation of a user of the medical institution is provided, and the medical software generation tool comprises a bounded surface display unit, a creation operation detection unit, a creation operation response unit, a dragging operation detection unit, a dragging operation response unit, a selected operation detection unit, a selected operation response unit, an editing operation detection unit, an editing operation response unit, a generation operation detection unit and a generation operation response unit.

On the basis of the technical solution of the first aspect, the present embodiment further provides a possible design for a user to select a page template, that is, when the page creation instruction includes a specified page type, a new page is created in a page column on the human-computer interaction interface, where the possible design includes, but is not limited to: firstly, displaying a plurality of page models corresponding to the page types on the human-computer interaction interface, wherein the page types can be but are not limited to software main pages or software sub-pages, a pre-templated functional component set is placed in a page editing window of each page model, and the functional component set comprises at least one functional component model; and then creating a new page which is the same as the selected page model in a page bar on the man-machine interaction interface according to a selection result of the medical institution user on the plurality of page models. As shown in fig. 2, for example, a "home" selection button and a "sub-page" end selection button are preset in the upper left dashed box area of the human-computer interaction interface, and the page type may be specified by clicking the "home" selection button or the "sub-page" end selection button. Further, the software main page/sub page may be subdivided into different types of main pages/sub pages based on functional categories, for example, the software sub page may be subdivided into an economic management class sub page, a drug management class sub page, a clinical diagnosis class sub page, a statistical analysis class sub page, and/or an external interface class sub page, and the like.

Preferably, a plurality of page models corresponding to the page types are displayed on the human-computer interaction interface, including but not limited to: firstly, acquiring a plurality of page models corresponding to the page types, wherein the page types can be but are not limited to software main pages or software sub-pages, a page editing window of each page model is provided with a pre-templated functional component set, and the functional component set comprises at least one functional component model; then, calculating the similarity between the corresponding page image and the established page image aiming at each page model in the multiple page models to obtain the corresponding image similarity, wherein the established page image refers to the page images of a plurality of pages which are arranged in the page column on the human-computer interaction interface in a descending order according to the creation time; and finally, displaying the plurality of page models on the human-computer interaction interface in a carousel mode according to the sequence of the similarity of the images from large to small. Because the created page images can reflect the recent page design style of the user (such as the typesetting layout style of functional components) to a certain extent, the page models similar to the recent page design style of the user can be preferentially recommended to the user through the calculation and sequencing results of the image similarity, so that the user can quickly select the expected software main page model or software sub-page model, the editing operation of the subsequent page design style is reduced, and the user experience is further improved. The method of calculating the image similarity is a conventional method, and for example, the method, the apparatus, and the storage medium "CN 109740633B, which is a conventional method of calculating image similarity" are referred to for calculation.

Therefore, based on the possible design I, a plurality of page templates to be selected can be provided for medical institution users in the page creation process, so that the users can select and establish a new page with the templated layout of the functional components, the subsequent user operation can be reduced, and the user experience can be improved; and a page model similar to the recent page design style of the user can be preferentially recommended to the user, so that the user can quickly select the expected software main page model or software sub-page model, the editing operation of the subsequent page design style is reduced, and the user experience is further improved.

On the basis of the technical solution of the first aspect, the present embodiment further provides a second possible design for a user to enrich the content of the design page, that is, the component model column further provides a plurality of different tag component models. The label component model can be but is not limited to a preset text label component model, a picture label component model, a sharing button label component model, an active label component model and/or a page label component model and the like.

The drag operation detection unit is further configured to detect whether a second component drag operation has occurred on the human-computer interaction interface, where the second component drag operation is a human-computer interaction operation in which the medical institution user drags a certain label component model from the component model column into the page editing window. The certain tag component model represents the tag component that the medical institution user wants to add in the page (i.e. as a non-functional component) in order to illustrate the corresponding tag information in the page, for example, providing an illustration mark symbol related to emergency registration, etc.

The drag operation response unit is further configured to, when it is detected that the second component drag operation has occurred, place, in the page editing window, a new tag component generated based on the certain tag component model according to a drag result of the second component drag operation. The new tag component is another content element that the medical institution user wants to add in the page, and the generation manner of the new tag component can be automatically generated based on the preset template content (for example, default information of the illustration position, the illustration shape, the illustration size or the illustration content) of the certain tag component model.

The selection operation detection unit is further configured to detect whether a second component selection operation has occurred on the human-computer interaction interface, where the second component selection operation is a human-computer interaction operation in which the medical institution user selects a certain tag component in the page editing window.

And the selected operation response unit is further configured to, when it is detected that the second component selected operation has occurred, display a component property editing window of the certain tag component on the human-computer interaction interface, where the component property editing window presents editable property information of the certain tag component, and the editable property information includes, but is not limited to, a diagram position, a diagram shape, a diagram size, a diagram content, and/or the like of the certain tag component in the located page. The graphic position includes but is not limited to a plane coordinate, a layer where the graphic position is located, and the like; the illustrated shape may be, but is not limited to, rectangular, circular, or the like; the graphical content may include, but is not limited to, pictures, text, and/or editable scripts for Canvas animation (which are executable files written according to a certain format, such as H5 scripts, to facilitate design personalization through a high-performance animation playback form in a page), and the like. In addition, the editable attribute information further includes, but is not limited to, a hyperlink address for triggering access after the pictorial content is clicked or a sub-page unique identifier for triggering switching loading of a certain software sub-page, where the certain software sub-page is a created page in the page column.

The editing operation detection unit is further configured to detect whether a second component editing operation has occurred on the human-computer interaction interface, where the second component editing operation is a human-computer interaction operation performed by the medical institution user to edit the editable attribute information in the component attribute editing window.

Therefore, based on the second possible design, the human-computer interaction operation of the user can be responded, so that the medical institution user can add the label assembly on the page and edit the label assembly on line, the content elements of the page are enriched, and the development and construction of medical service software meeting personalized requirements are further facilitated. Furthermore, the graphic information such as graphic position, graphic shape, graphic size, graphic content, and the like for the functional component can also be edited online based on the component property editing window.

Based on the above technical solution of the second possible design, the present embodiment further provides a third possible design that can perform a tab component stack type composition design based on a drag result of the tab component model, that is, according to the drag result of the drag operation of the second component, a new tab component generated based on the certain tab component model is placed in the page editing window, including but not limited to: firstly, according to a dragging result of the dragging operation of the second component, determining a diagram position of a new label component in the new page, wherein the diagram position is generated based on a certain label component model and comprises a plane coordinate and a layer where the diagram position is located; and placing the new tag assembly in the page editing window according to the diagram position.

Specifically, the determining, according to the dragging result of the second component dragging operation, the illustrated position of the new tab component in the new page, which is generated based on the certain tab component model, includes, but is not limited to: firstly, according to a dragging result of the dragging operation of the second component, obtaining a dragging track of the certain label component model in the page editing window, wherein the dragging track comprises an abscissa and an ordinate of the certain label component model in the page editing window at each dragging moment; then according to the dragging track, determining a track end point and a track point with the maximum stay time; on the last hand, according to the abscissa and/or the ordinate in the track end point, determining the plane coordinate of a new label assembly in the new page, wherein the new label assembly is generated based on the certain label assembly model; on the other hand, whether at least one placed label assembly (namely, a label assembly generated and displayed based on an earlier label assembly dragging operation) exists in the page editing window is judged, if not, the layer where the new label assembly exists in the new page is determined as a bottom layer (namely, a layer lower than the layer where all label assemblies are generated later) and when the at least one placed label assembly exists in the page editing window, whether the corresponding stay time of the track point is greater than or equal to a preset time threshold value is judged, if so, a certain placed label assembly with the plane position closest to the track point in the page editing window is determined from the at least one placed label assembly, and the layer where the new label assembly exists in the new page is determined as the layer where the certain placed label assembly exists in the new page, otherwise, the layer where the new label assembly exists in the new page is determined as a top layer (namely, a layer higher than one layer where all the placed label assemblies exist). The maximum stay time is the maximum time for pausing movement in the label assembly model dragging operation process, and the dragging track comprises the abscissa and the ordinate of a certain label assembly model in the page editing window at each dragging moment, so that the track point with the maximum stay time can be determined based on each dragging moment. For example, as shown in fig. 2, if three placed tab components are placed in the page editing window: the method comprises the steps that a tag component 1, a tag component 2, a tag component 3 and the like are generated through a new tag component model dragging operation, a new tag component 4 is generated, a track point A with the maximum stay time is determined according to a dragging track, at the moment, if the maximum stay time is smaller than a time threshold (for example, 1 second), a layer where the tag component 4 is located in a new page is determined as a top layer, and if the maximum stay time is larger than or equal to the time threshold, the distance from a plane position in a page editing frame to the track point A is found to be the shortest, the layer where the tag component 4 is located in the new page can be determined as the layer where the tag component 2 is located in the new page, namely, the tag component 4 and the tag component 2 are directly enabled to be on the same layer, further, the subsequent editing operation of the layer position is not needed, and the operation convenience and user experience of a user are further improved.

Therefore, based on the third possible design, the label component stacking type-setting design effect can be achieved based on the label component model dragging result, a medical institution user can conveniently display more label information by using a limited page area, the plane coordinate of the new label component in the new page can be directly determined through a special dragging operation, the layer where the new label component is located in the new page is also directly determined based on the layer where the label component is located in the new page, further, the subsequent editing operation of the graphic position is not needed, and the operation convenience and the user experience of the user can be further improved.

Finally, it should be noted that the present invention is not limited to the above alternative embodiments, and that various other forms of products can be obtained by anyone in light of the present invention. The above detailed description should not be taken as limiting the scope of the invention, which is defined in the claims, and which the description is intended to be interpreted accordingly.

Claims

1. A low code platform facing a medical institution is characterized in that the low code platform is used as a medical software generation tool and comprises an interface display unit, a creation operation detection unit, a creation operation response unit, a dragging operation detection unit, a dragging operation response unit, a selected operation detection unit, a selected operation response unit, an editing operation detection unit, an editing operation response unit, a generation operation detection unit and a generation operation response unit;

the creation operation detection unit is in communication connection with the interface display unit and is used for detecting whether page creation operation has occurred on the human-computer interaction interface, wherein the page creation operation refers to human-computer interaction operation of a medical institution user triggering a page creation instruction on the human-computer interaction interface;

the selected operation detection unit is in communication connection with the interface display unit and is used for detecting whether a first component selected operation occurs on the human-computer interaction interface, wherein the first component selected operation refers to a human-computer interaction operation of a medical institution user selecting a certain functional component in the page editing window;

2. The facility-oriented low-code platform according to claim 1, wherein the functional component models comprise an economic management functional component model, a drug management functional component model, a clinical diagnosis functional component model, a statistical analysis functional component model and/or an external interface functional component model, wherein the economic management functional component model comprises an outpatient registration component model, an outpatient service pricing component model, an admission management component model and/or an in-patient billing component model, the drug management functional component model comprises a drug depot management component model, an outpatient pharmacy management component model, an in-patient pharmacy management component model and/or a drug pricing management component model, the clinical diagnosis functional component model comprises an outpatient doctor workstation component model and/or a nurse workstation component model, the statistical analysis functional component model comprises a medical statistics component model, a hospital comprehensive query and analysis component model and/or a health bureau comprehensive query and analysis component model, and the external interface functional component model comprises a medical insurance system interface component model, a two-way medical system interface component model, a remote medical care system interface model and/or a consulting system interface model.

3. The medical institution-oriented low-code platform of claim 1, wherein when the page creation instruction contains a specified destination, a page edit window of the new page is presented on the human-machine interface, comprising: and displaying a page editing window of the new page on the man-machine interaction interface, wherein the page editing window is matched with a display screen of the target terminal, and the target terminal is a smart phone terminal or a Personal Computer (PC) terminal.

4. The healthcare facility-oriented low-code platform of claim 1, wherein when the page creation instruction contains a specified page type, creating a new page in a page bar on the human-machine interface comprises:

5. The healthcare facility-oriented low code platform of claim 4, wherein presenting a plurality of page models corresponding to the page types on the human-machine interface comprises:

and displaying the plurality of page models on the human-computer interaction interface in a carousel mode according to the sequence of the image similarity from large to small.

6. The medical-institution-oriented low-code platform of claim 1, wherein the component model column is further provided with a plurality of different tagged component models;

the dragging operation detection unit is further configured to detect whether a second component dragging operation has occurred on the human-computer interaction interface, where the second component dragging operation refers to a human-computer interaction operation in which the medical institution user drags a certain label component model from the component model bar into the page editing window;

7. The medical-institution-oriented low-code platform as claimed in claim 6, wherein the editable attribute information further comprises a hyperlink address for triggering access after clicking on the pictorial content or a sub-page unique identifier for triggering switching loading of a certain software sub-page, wherein the certain software sub-page is a created page in the page column.

8. The medical-institution-oriented low-code platform of claim 1, wherein node editing of the graphical flow network in the graphical editing window comprises:

9. The medical-institution-oriented low-code platform of claim 1, wherein updating the graphical process network that stores the certain functional component based on the edit result of the first component editing operation comprises:

10. The medical-institution-oriented low-code platform as claimed in claim 1, wherein when the software generation instruction contains a specified target system, generating medical service software according to the edit result of each page of the at least one page comprises: