CN117596297B - Complex virtual instrument software aggregation method - Google Patents

Abstract

The invention provides a complex virtual instrument software aggregation method, which belongs to the technical field of Internet of things, and realizes information integration among a plurality of complex virtual instrument software by taking a monitoring unit as a unit by deploying complex virtual instrument software of a plurality of similar application scenes and performing aggregation configuration, wherein the complex virtual instrument software is divided into an aggregation node and an aggregated node, data transmission and communication can be flexibly performed through an interoperation interface, cooperation and unification among the nodes are ensured, integrated application of aggregated node information in the aggregation node can be realized by the method, and the information of the complex virtual instrument software is integrated and processed under the condition that the complex virtual instrument software is not required to be modified, so that the expandability and the data utilization efficiency of the complex virtual instrument software are improved.

Description

Complex virtual instrument software aggregation method

Technical Field

The invention belongs to the technical field of the Internet of things, and particularly relates to a complex virtual instrument software aggregation method.

Background

With the development of technology, virtual instrument technology is widely used in various testing, measuring and automation applications. However, conventional virtual instrument software virtualizes only the functions of one physical instrument, and has some limitations in adapting to complex environments and diverse applications. The complex virtual instrument software can better adapt to complex environments and variable application requirements by introducing the sensing data management of various physical instruments taking the monitored object as a core, and can conveniently collect, analyze and store the sensing data of various physical instruments and comprehensively analyze the state of the monitored object.

However, current complex virtual instrument software still has some challenges in terms of information integration and scalability. The existing method cannot realize rapid information collection, information integration among different complex virtual instrument software is inconvenient, complicated integrated software development is needed, data processing efficiency is low, and complex virtual instrument software cannot be flexibly expanded.

Thus, there is a need for improved information integration and scalability of complex virtual instrument software nodes. By improving the information integration method, information can be conveniently collected among different complex virtual instrument software, the efficiency and speed of data processing and the flexibility and convenience of the whole system are improved, the system can be flexibly expanded, and the system is suitable for application scenes with different scales and requirements.

Disclosure of Invention

In view of this, the invention provides a complex virtual instrument software aggregation method, which is capable of improving the utilization efficiency of data by configuring complex virtual instrument software and calling an interoperation interface to realize information integration between complex virtual instrument software, thereby providing convenient and rapid aggregation for complex virtual instrument software.

The invention is realized in the following way:

The invention provides a complex virtual instrument software aggregation method, wherein the aggregation method is to deploy complex virtual instrument software of a plurality of similar application scenes, aggregate configuration is carried out on the complex virtual instrument software, the complex virtual instrument software calls an interoperation interface according to configuration information, and finally information integration among the complex virtual instrument software by taking a monitoring unit as a unit is realized.

The complex virtual instrument software is a software system taking monitored object data as a core, and comprises sensor data acquisition, transmission, processing, intelligent analysis and data visualization.

The complex virtual instrument software performs data transmission through a network protocol, each complex virtual instrument software can have a plurality of network addresses, and each complex virtual instrument software has non-repeated addresses and can access each other in the same network.

The monitoring unit refers to a logic grouping of sensing parameters determined according to application requirements in complex virtual instrument software, and each sensing parameter corresponds to a data type of a specific sensor or is a data type calculated according to a group of sensing data acquired at the same time.

The monitoring units and the sensing parameters are in a many-to-many relation, a single monitoring unit can contain a plurality of sensing parameters, the single sensing parameter can also be contained by a plurality of monitoring units, meanwhile, the plurality of monitoring units can be logically combined into one navigation node, and the single monitoring unit can only be used as a child node of the single navigation node.

The aggregation configuration refers to setting aggregation association information on complex virtual instrument software in order to realize complex virtual instrument software aggregation.

The complex virtual instrument software is divided into two types, namely an aggregation node and an aggregated node, only the aggregation node is needed to conduct aggregation configuration, the configuration of the aggregated node is transmitted by the aggregation node through an interoperation interface, the aggregation node can aggregate a plurality of nodes at the same time, the aggregated node can also be aggregated by a plurality of aggregation nodes at the same time, and the aggregation node and the aggregated node form an aggregate.

The aggregation association information of the complex virtual instrument software refers to key information used in the aggregation process of the complex virtual instrument software, and the aggregation association information setting item comprises the type of the complex virtual instrument software, the connection information of the aggregated node, and the data transmission mode between the aggregated node and the aggregated node.

The connection information of the node to be aggregated is the access address of the node to be aggregated, and the interoperation interface can be called to communicate through the connection information.

The data transmission mode between the aggregation node and the aggregated node comprises active transmission and passive transmission, wherein the active transmission means that the aggregation node actively calls an interoperation interface to acquire data from the aggregated node; the passive transmission means that the aggregation node waits for the aggregated node to call the interoperation interface to upload data to the aggregation node, and the aggregation node passively receives the data for processing and then stores the data.

The interoperation interface refers to a communication rule and a data exchange format between complex virtual instrument software, and comprises an aggregation associated information transfer interface, an aggregation data acquisition interface, an aggregation data uploading interface and an aggregation operation feedback interface.

The aggregation association information transmission interoperation interface is responsible for transmitting aggregation association information provided by the aggregation node to the aggregated node, the transmitted parameters comprise an access address of the aggregation node, a data transmission mode between the aggregation node and the aggregated node, and when the aggregation association information transmission interoperation interface of the complex virtual instrument software is called, the complex virtual instrument software is defaulted to be the aggregated node, and the complex virtual instrument software decides to execute data uploading or wait for a data acquisition request according to the aggregation association information provided by the aggregation node.

The aggregation data acquisition interoperation interface of the aggregated node is actively initiated and invoked by the aggregated node and is responsible for transmitting data which is actively requested by the aggregated node to each aggregated node; the aggregation data uploading interoperation interface of the aggregation node is actively initiated and invoked by the aggregated node and is responsible for transmitting node data actively uploaded to the aggregation node by the aggregated node; the aggregation operation feedback interoperation interface of the aggregated node is actively initiated and invoked by the aggregated node and is responsible for transmitting operation data which is generated at the aggregated node and can enable the data of the aggregated node to be updated.

The information integration means that the aggregation node integrates navigation node information and monitoring unit information of the aggregated node, and integrated application is carried out on complex virtual instrument software of the aggregation node.

Wherein the navigation node information includes: the basic information of the navigation node, and the inclusion relation between the navigation node and the monitoring unit.

Wherein the monitoring unit information includes: basic information of a monitoring unit, monitoring record metadata, states of the monitoring unit, descriptive information of sensing parameters, monitoring values of the sensing parameters and inclusion relation between the monitoring unit and the sensing parameters.

The integrated application of the navigation node information refers to that in complex virtual instrument software of the aggregation node, the integrated navigation node information is displayed in a tree navigation and map navigation mode and is used for switching a display interface of a monitoring unit by the software, and the integrated navigation node set comprises a navigation node set of the aggregation node and a navigation node set of the aggregated node.

The monitoring unit information integration application refers to the use of the integrated monitoring unit operation software function in the aggregation node, the integrated monitoring unit of the aggregation node is the union of the aggregation node and all the monitoring unit sets of the aggregation node, and the original monitoring unit operation software function of the aggregation node can be applied to the integrated monitoring units of all the aggregation nodes.

Wherein the software functions operating on the monitoring unit include: and managing the monitoring data, displaying the monitoring curve, and analyzing and processing the monitoring data.

Compared with the prior art, the complex virtual instrument software aggregation method provided by the invention has the beneficial effects that: according to the invention, the information among the plurality of complex virtual instrument software nodes can be integrated, the complex virtual instrument software can be integrated and processed without modifying the complex virtual instrument software, so that the complex virtual instrument software nodes are coordinated and unified, and the data utilization efficiency is improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the description of the embodiments of the present invention will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is an example of basic information of complex virtual instrument software in an embodiment of the invention;

FIG. 2 is a complex virtual instrument software aggregate relationship in an embodiment of the invention;

FIG. 3 is a configuration state of each node after the transmission of aggregation-related information in an embodiment of the present invention;

FIG. 4 is an interactive timing sequence of an active transmission mode according to an embodiment of the present invention;

Fig. 5 is an interactive timing sequence of a passive transmission mode in an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

As shown in fig. 1, the basic information of a plurality of deployed complex virtual instrument software provided by the embodiment of the present invention, where node a has an address A1, which is an aggregation node; the node B has an address B1 and is an aggregation node; node a has address a1, which is the node to be aggregated; node b has addresses b1 and b2, which are aggregated nodes; node c has address c1 and is the node being aggregated.

Exemplary, as shown in fig. 2, an aggregation relationship between complex virtual instrument software provided by the embodiment of the present invention is that an aggregation node a aggregates aggregated nodes a and B, an aggregation node B aggregates aggregated nodes B and c, the aggregation node a and the aggregated nodes a and B form an aggregate 1, and the aggregation node B and the aggregated nodes B and c form an aggregate 2.

Further, after the complex virtual instrument software is deployed, the complex virtual instrument software of the aggregation node needs to be configured according to the aggregation relation, and the configuration mode of the complex virtual instrument software node aggregation configuration can be one or more of interface call, interface interaction and configuration files.

The data transmission mode of the aggregation node A is configured as active transmission, and is configured by the aggregation node address as an address a1 of the node a and an address B1 of the node B respectively, and the data transmission mode of the aggregation node B is configured as passive transmission, and is configured by the aggregation node address as an address B2 of the node B and an address c1 of the node c respectively.

Further, after the aggregation configuration of the aggregation node is completed, the aggregation node transmits configuration information to the node to be aggregated through the aggregation association information transfer interoperation interface, as shown in fig. 3, which is a configuration state of each node after the aggregation association information is transferred, where the node A, B respectively transmits, to the configured address of the node to be aggregated through the aggregation association information interoperation interface, an access address and a data transmission mode of the aggregation node, and the node to be aggregated receives the access address and the data transmission mode of the aggregation node and records the access address and the data transmission mode of the aggregation node. The address and data transmission mode of the aggregation node recorded by the node a are as follows: { Address A1: active transmission }; the address and data transmission mode of the aggregation node recorded by the node b are as follows: { Address A1: active transfer, address B1: passive transmission }; the address and data transmission mode of the aggregation node recorded by the node c is as follows: { Address B1: passive transmission }.

In particular, the manner in which the inter-operation interface is invoked between complex virtual instrument software may be one of TCP, HTTP, webSocket, RPC.

Further, after the transmission of the aggregation association information is completed, the complex virtual instrument software in each aggregation body starts information integration according to the aggregation association information.

For the aggregate 1, the aggregation node is node a, the data transmission mode is active transmission, the interaction time sequence is shown in fig. 4, when the user initiates the information integration request at the aggregation node a, the aggregation node a initiates the data acquisition request to the aggregated nodes a and b respectively in a parallel mode through the aggregation data acquisition interoperation interface, the data is returned after being responded by the aggregation nodes a and b, and the aggregation node a displays the information integration result and feeds back the information integration result to the user after performing aggregation processing.

For the aggregation 2, the aggregation node is a node B, the data transmission mode is passive transmission, the interaction time sequence is shown in fig. 5, after the aggregated nodes B and c of the aggregation node B record aggregation association information, original node data needs to be uploaded to the aggregation node B through an aggregation data uploading interoperation interface, the aggregation data uploading interoperation interface is called to update the node data to the aggregation node B when the subsequent node data is updated, and when a user initiates an information integration request at the aggregation node B, the aggregation node B performs aggregation processing on the stored data of the aggregated nodes B and c, and the processing is completed, and information integration result display is fed back to the user.

Optionally, when the aggregation node performs the software function operation, if the operation can update the data of the aggregated node, the operation is transferred to the affected aggregated node through the aggregation operation feedback interoperation interface.

Further, for integrated applications after navigation node information integration, the navigation nodes are checked in a tree navigation or map navigation mode.

The navigation node information includes a node number, a node name, a node longitude, a node latitude, a node icon, and a monitoring unit number included in a navigation node, and in the aggregated navigation example provided by the embodiment of the invention, the node a integrates self navigation node information and navigation node information of the aggregated nodes a and b to form a tree navigation node set, so that the tree navigation can be further switched into map navigation to check the geographical position distribution of each navigation node, the navigation node in the map navigation can be selected to check the monitoring unit included in the map navigation, for example, the monitoring unit 1 and the monitoring unit 2 included in the map navigation can be displayed if the node a_navigation A1 is clicked, and the integrated application of the monitoring unit can be realized by clicking a button corresponding to the monitoring unit.

Further, for integrated application of the integrated monitoring unit information, the method comprises the steps of managing the monitoring data, displaying the monitoring curve, and analyzing and processing the monitoring data.

Specifically, when the monitoring unit is selected in the tree navigation or the map navigation, the monitoring data of the corresponding complex virtual instrument software can be managed, including operations such as checking basic information of the monitoring unit, changing the state of the monitoring unit, retrieving monitoring record metadata and the like.

Specifically, after the metadata of the monitoring record are retrieved, a detailed monitoring data list of the sensing parameters corresponding to the monitoring record can be checked, at the moment, the monitoring data can be selected, and curve drawing and analysis calculation are performed on the data on the basis.

Specifically, for data curves, printing, scaling, moving, marking data points can be performed; for data analysis and calculation, the data analysis and calculation can be processed, calculated and analyzed by combining a specific algorithm, and finally a report is generated.

Claims (6)

1. The aggregation method is characterized by being used for deploying complex virtual instrument software of a plurality of similar application scenes, carrying out aggregation configuration on the complex virtual instrument software, calling an interoperation interface by the complex virtual instrument software according to configuration information, and integrating information among the complex virtual instrument software by taking a monitoring unit as a unit;

The aggregation configuration is used for realizing that complex virtual instrument software is aggregated to set aggregation association information on the complex virtual instrument software, the complex virtual instrument software is divided into two types of aggregated nodes and aggregated nodes, the aggregated nodes are subjected to aggregation configuration, the configuration of the aggregated nodes is transmitted by the aggregated nodes through an interoperation interface, and the aggregated nodes form an aggregate;

The aggregation association information of the complex virtual instrument software refers to association information used in the aggregation process of the complex virtual instrument software, and comprises types of the complex virtual instrument software, connection information of aggregated nodes and data transmission modes between the aggregated nodes;

the complex virtual instrument software is a software system taking monitored object data as a core, and comprises sensor data acquisition, transmission, processing, intelligent analysis and data visualization.

2. The method for aggregating complex virtual instrument software according to claim 1, wherein the monitoring unit refers to a logical grouping of sensing parameters determined according to application requirements in the complex virtual instrument software, and each sensing parameter corresponds to a data type of a specific sensor or is a data type calculated according to a group of sensing data collected at the same time.

3. The method for aggregating complex virtual instrument software according to claim 2, wherein the interoperable interfaces refer to communication rules and data exchange formats among complex virtual instrument software, and include an aggregate configuration transfer interface, an aggregate data acquisition interface, an aggregate data uploading interface, and an aggregate operation feedback interface.

4. A method for aggregating complex virtual instrument software according to claim 3, wherein the information integration means that the aggregation node integrates navigation node information and monitoring unit information of the aggregated node, and the complex virtual instrument software is integrated and applied to the aggregated node.

5. The method for aggregating complex virtual instrument software according to claim 4, wherein the application of integrating navigation node information refers to displaying integrated navigation node information in a tree navigation and map navigation mode in the complex virtual instrument software of an aggregated node, and the integrated navigation node set includes a navigation node set of the aggregated node and a navigation node set of the aggregated node.

6. The method for aggregating software of complex virtual machines according to claim 5, wherein the application of the information of the monitoring units refers to the use of the integrated monitoring units by the aggregation node, the integrated monitoring units of the aggregation node are the union of the aggregation node and the aggregate of all the monitoring units of the aggregation node, and the original software functions of the aggregation node for operating the monitoring units are applied to the integrated monitoring units of all the aggregation nodes.