CN111818184A - Medical Internet of things message routing device and method based on visual convenient flow calculation - Google Patents

Abstract

The invention provides a medical Internet of things message routing device and method based on visual convenient flow calculation. The message routing device comprises a process factory, a process center, a process engine and a process configuration module. The process plant is used to store standardized professional nodes. The flow center is used for storing the configured message routing flow. The flow engine decomposes all message routing flows of the flow center into nodes and connecting lines, and processes and sends the received data according to the configured message routing flows in the flow center after the data to be processed is transmitted to the message routing device. The invention solves the technical blank of the medical Internet of things field in the prior art, supports transverse expansion, can expand nodes by self-definition, and endows the nodes with corresponding functions.

Description

Medical Internet of things message routing device and method based on visual convenient flow calculation

Technical Field

The invention relates to the field of data processing of medical internet of things, in particular to a medical internet of things message routing device and method based on visual convenient flow calculation.

Background

The invention can carry out the operations of encoding/decoding, storing, forwarding, screening, early warning and the like on the medical terminal data. One implementation scheme that is similar to the present invention in the prior art is an activity workflow: the workflow is to organize a group of tasks to complete a certain business, and defines the triggering sequence and triggering conditions of the tasks. However, this solution is not applied in the field of medical data, such as data processing, but is often applied in the field of personnel in enterprises, such as: employee leave system, etc. Obviously, in the field of medical internet of things, the workflow lacks professional medical internet of things technology nodes, such as: data encoding/decoding, internet of things protocol nodes, etc., and this workflow does not allow for the extension of nodes with targeted transactions.

In contrast, the invention is generated aiming at the field of medical internet of things, so the invention naturally accords with the field of medical internet of things, has data coding/decoding, mqtt nodes and the like, provides strong expandability, and can add nodes with any transaction processing mode to users.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a medical Internet of things message routing device and method based on visual convenient flow calculation, wherein the device comprises the following steps: the data transmission process of the hospital equipment terminal is managed in a visual configuration interface mode, and automation of equipment data processing, clinical data entry and clinical data display is achieved.

The terminal adapter and an open platform (openApi) opened to a third party application are used as a client of the message routing device, and the message routing device is used as a server. The terminal adapter and the open platform (openApi) are used as an access layer of the platform, the access layer is used as an inlet of the message routing device, data are subjected to standardized processing, the processed data are transmitted to the message routing device, the data are subjected to a series of processing through the message routing device and finally flow to the storage and application layer, and the data are stored and displayed.

A medical Internet of things message routing device based on visual convenient flow calculation comprises a flow factory, a flow center, a flow engine and a flow configuration module.

The process factory is used for storing standardized professional nodes. The standardized professional nodes are used as abstractions of all transaction processing processes in the process, include unique node identification, node functions and classes to which the nodes belong, can be expanded in a user-defined mode, and endow the nodes with corresponding functions.

The flow center is used for storing the configured message routing flow. The message routing process is displayed on a management interface of the process configuration module in a graphical mode, and multiple operations of creating, editing and deleting can be carried out in the process configuration module.

The flow configuration module is connected with the flow factory and the flow center and used for configuring message routing flows, a management interface of the flow configuration module provides standardized professional nodes stored in the flow factory and connecting lines with condition judgment, the nodes are used for completing specific affairs and functions, and the connecting lines are used for screening message data and eliminating redundant data before the data enters the next flow node. The connecting line comprises a classification of the connecting line, a calculation expression supported by a name and a verification operation on data.

The flow engine decomposes all message routing flows of the flow center into nodes and connecting lines, and processes and sends the received data according to the configured message routing flows in the flow center after the data to be processed is transmitted to the message routing device.

A medical Internet of things message routing method based on visual convenient flow calculation comprises the following steps.

And (1) entering a management interface of the process configuration module, and initializing all nodes in the process factory and connecting lines in the process configuration module.

And (2) carrying out route flow configuration on the corresponding terminal through a flow configuration module aiming at the required clinical data, and sending the configured terminal to a flow center for management after the configuration is finished.

And (3) standardizing the input data through a terminal adapter and an open platform which is open to a third party application, and then sending the standardized data to a message routing device. When the message routing device receives the data after the standardized processing, the flow engine loads the configured routing flow.

Step (4), when executing the configured routing flow, the flow engine will decompose the routing flow into nodes and connecting lines; firstly, data to be processed is imported into a Start node, and each message routing flow has one Start node as an entrance of the whole message routing flow.

Step 5, the process engine moves to a corresponding node according to the triggering sequence and the triggering condition corresponding to the connecting line; and the data entering from the Start node is screened or verified through the connecting line.

And (6) processing the data by the nodes with corresponding functions, wherein the processing of the corresponding functions comprises encoding/decoding, storing, forwarding, screening and early warning. And the data to be processed enters the message routing flow from the Start node, the screened or verified data is led into the next node through one or more connecting lines, and the process is repeated in a circulating way until the data processing of all the connecting lines and the nodes in the message routing flow is finished.

And (7) sending the data processed by the message routing process to the storage layer and the application layer.

The data storage and application layer comprises edr a data center, a digital panel and a third party application. edr data center is used for storing final data, digital panel is used for clinical data display and equipment control, and the third party application includes hospital HIS system and intelligent Internet of things delivery room system.

The invention has the following beneficial effects.

1. The invention solves the technical blank of the prior art in the field of medical Internet of things, and the technical blank comprises professional technical nodes of the medical Internet of things and butt joint aiming at a third-party system, such as: and the hospital HIS system and the like are formatted into corresponding data packets and forwarded functional nodes.

2. The invention supports transverse expansion, can self-define expansion nodes and endows the nodes with corresponding functions; the nodes which can be expanded by self-definition comprise a general node and a special node, wherein the general node comprises a storage node mysql (data is stored in a mysql database), infilxdb (data is stored in a time sequence database infilxdb), excepting (message routing exception information is stored), mongodb (data is stored in a mongo database) and the like, communication protocol nodes comprise mqtt (mqtt protocol), http (http protocol), rpc (rpc protocol) and the like, a process starting node star, a process ending node end, a time node delay, a message protocol node map (converted into a map set), list (converted into a list set), array (converted into an array set), json encode (data encoding), and json decode (data decoding); besides its general nodes, special nodes are extended to solve some service scenario problems, such as getDeviceInfo node (get device information), bytesToMap (byte to map set).

Drawings

Fig. 1 is a flow chart of a message routing method of the present invention.

Fig. 2 is a block diagram of a message routing apparatus according to the present invention.

Detailed Description

The invention is further illustrated by the following examples in conjunction with the accompanying drawings.

The invention realizes permanent automatic operation and data processing after one-time configuration.

As shown in fig. 2, a medical internet of things message routing apparatus based on visualization convenient flow calculation includes a flow factory, a flow center, a flow engine, and a flow configuration module.

The process factory is used for storing standardized professional nodes. The standardized professional nodes are used as abstractions of all transaction processing processes in the process, comprise unique node identification, node functions and node belonging classifications, can be expanded in a user-defined mode, and endow corresponding functions to the nodes; the standardized professional nodes are used as abstractions of all transaction processing processes in the process, so that the processing process of an operator on the complex medical Internet of things data process is simplified, the professional requirement degree of the operator is reduced, and the third party application can conveniently expand a new transaction processing process.

The flow center is used for storing the configured message routing flow. The message routing process is displayed on a management interface of the process configuration module in a graphical mode, and multiple operations of creating, editing and deleting can be carried out in the process configuration module.

The flow configuration module is connected with the flow factory and the flow center and used for configuring message routing flows, a management interface of the flow configuration module provides standardized professional nodes stored in the flow factory and connecting lines with condition judgment, the nodes are used for completing specific affairs and functions, and the connecting lines are used for screening message data and eliminating redundant data before the data enters the next flow node. The connecting line comprises a classification of the connecting line, a calculation expression supported by a name and a verification operation on data.

The flow engine decomposes all message routing flows of the flow center into nodes and connecting lines, and processes and sends the received data according to the configured message routing flows in the flow center after the data to be processed is transmitted to the message routing device.

As shown in fig. 1, a medical internet of things message routing method based on visualization convenient flow calculation includes the following steps.

And (1) entering a management interface of the process configuration module, and initializing all nodes in the process factory and connecting lines in the process configuration module.

And (2) carrying out route flow configuration on the corresponding terminal through a flow configuration module aiming at the required clinical data, and sending the configured terminal to a flow center for management after the configuration is finished.

And (3) standardizing the input data through a terminal adapter and an open platform which is open to a third party application, and then sending the standardized data to a message routing device. When the message routing device receives the data after the standardized processing, the flow engine loads the configured routing flow.

Step (4), when executing the configured routing flow, the flow engine will decompose the routing flow into nodes and connecting lines; firstly, data to be processed is imported into a Start node, and each message routing flow has one Start node as an entrance of the whole message routing flow.

Step 5, the process engine moves to a corresponding node according to the triggering sequence and the triggering condition corresponding to the connecting line; and the data entering from the Start node is screened or verified through the connecting line.

And (6) processing the data by the nodes with corresponding functions, wherein the processing of the corresponding functions comprises encoding/decoding, storing, forwarding, screening and early warning. And the data to be processed enters the message routing flow from the Start node, the screened or verified data is led into the next node through one or more connecting lines, and the process is repeated in a circulating way until the data processing of all the connecting lines and the nodes in the message routing flow is finished.

And (7) sending the data processed by the message routing process to the storage layer and the application layer.

The data storage and application layer comprises edr a data center, a digital panel and a third party application. edr data center is used for storing final data, digital panel is used for clinical data display and equipment control, and the third party application includes hospital HIS system and intelligent Internet of things delivery room system.

Claims (3)

1. A medical Internet of things message routing device based on visual convenient flow calculation is characterized by comprising a flow factory, a flow center, a flow engine and a flow configuration module;

the process factory is used for storing standardized professional nodes; the standardized professional nodes are used as abstractions of all transaction processing processes in the process, comprise unique node identification, node functions and node belonging classifications, can be expanded in a user-defined mode, and endow corresponding functions to the nodes;

the flow center is used for storing the configured message routing flow; the message routing process is displayed on a management interface of the process configuration module in a graphical mode, and multiple creating, editing and deleting operations can be performed in the process configuration module;

the flow configuration module is connected with the flow factory and the flow center and used for configuring message routing flows, a management interface of the flow configuration module provides standardized professional nodes stored in the flow factory and connecting lines with condition judgment, the nodes are used for completing specific affairs and functions, and the connecting lines are used for screening message data and eliminating redundant data before the data enters the next flow node; the connecting line comprises a classification of the connecting line, a calculation expression supported by a name and a verification operation on data;

the flow engine decomposes all message routing flows of the flow center into nodes and connecting lines, and processes and sends the received data according to the configured message routing flows in the flow center after the data to be processed is transmitted to the message routing device.

2. The medical internet of things message routing device based on the visualized convenient flow calculation is characterized by comprising the following use method steps:

step (1), entering a management interface of a process configuration module, and initializing all nodes in a process factory and connecting lines in the process configuration module;

step (2), carrying out route flow configuration on a corresponding terminal through a flow configuration module aiming at the required clinical data, and sending the configured terminal to a flow center for management after the configuration is finished;

step (3), standardizing the input data through a terminal adapter and an open platform which is open to a third party application, and then sending the standardized data to a message routing device; when the message routing device receives the data after the standardized processing, the flow engine loads the configured routing flow;

step (4), when executing the configured routing flow, the flow engine will decompose the routing flow into nodes and connecting lines; firstly, importing data to be processed into a Start node, wherein each message routing flow has one Start node as an entrance of the whole message routing flow;

step 5, the process engine moves to a corresponding node according to the triggering sequence and the triggering condition corresponding to the connecting line; screening or verifying data from the Start node through a connecting line;

processing the data by the nodes with corresponding functions, wherein the processing of the corresponding functions comprises encoding/decoding, storing, forwarding, screening and early warning; the data to be processed enters the message routing flow from the Start node, the screened or verified data is led into the next node through one or more connecting lines, and the process is repeated in a circulating mode until the data processing of all the connecting lines and the nodes in the message routing flow is finished;

and (7) sending the data processed by the message routing process to the storage layer and the application layer.

3. The medical internet of things message routing device based on visualization convenient flow calculation as claimed in claim 2, wherein the data storage and application layer comprises edr data center, digital panel and third party system; edr data center is used for storing final data, digital panel is used for clinical data display and equipment control, and the third party system comprises hospital HIS system and intelligent Internet of things delivery room system.

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