KR20190135299A - Web based control monitoring intergrated system - Google Patents

Abstract

An objective of the present invention is to provide a web-based integrated control monitoring system which allows a client to easily manage a process system and equipment. According to the present invention, the integrated control monitoring system comprises: a data providing unit; a data collection unit including a plurality of agents to convert data acquired from the data providing unit by an action module into a resource format; a cloud server to store and manage resources received from the data collection unit; and a data visualization tool to map resources received from the cloud server with visual elements to visualize the resources.

Description

Web based control monitoring integrated system {WEB BASED CONTROL MONITORING INTERGRATED SYSTEM}

The present invention relates to a Web-based control monitoring system integration, and more particularly to an integrated system for managing and monitoring the system processes and equipment using the visualization tool.

The field of control monitoring needs to rely on individual development because of the diverse sources and formats of data (databases, files, industrial protocols of equipment and equipment, analog signals of sensors, etc.) and intuitive visual recognition.

In particular, in the case of control monitoring of systems and IOT devices, equipment, and facilities, a change in the source or format of data or the addition of an object to be monitored can be very expensive to change and manage the program.

If you use existing authoring tools (Power BI, Daisy, Tablo, ClickView, etc.) to minimize individual development, Business Intelligence (BI) tools focused on data analysis can turn data into appropriate visual elements such as charts or gauges. Although it is expressive, it lacks the freedom to author or create intuitive visualizations, or lack the ability to access, share (collaborate) and control (control) the Web.

Tools such as National Instruments LabView for testing and visualizing engineering systems are professional tools with high degree of freedom, but require programming to use, and are not designed to be advantageous, integrating them into data collection, supply, and collaboration. There is a problem that is not.

The limitations of the prior art will be described in more detail by dividing into a data acquisition and collection step, a data management and supply step, a control screen authoring step, and a control screen view step.

First, in the data acquisition and collection stage, there is a problem that the collection program must be developed separately because the sources and formats of the data are various. In addition, when accessing data directly from existing data visualization tools through connection information, a problem may occur in which connection information or data such as a database or a device is exposed in a network area.

Next, in the data management and supply phase, the visualization tools in the existing data analysis tools collect data because they are responsible for visualization and analysis after the data has already been acquired. Servers that manage and supply them to visualization services must be developed separately. In addition, the collected data needs to be archived for charting or comparison with past records. It is necessary to set the collection frequency to set the cumulative number of times or to update the data, and the rule on data removal should be included to prevent the data from growing indefinitely. There is a characteristic factor of such control system data management. Since such a management system is not provided, it requires subjective experience and relies on individual development. Furthermore, in the case of a request / server response structure of a client in which a relationship between a server supplying data and a client (control screen) using the data is general, the client continues to check whether the data has been changed even if there is no actual data change. The request can be sent to the server, causing unnecessary load on the server.

Next, the existing visualization tools that focus on data visualization and analysis at the control screen authoring stage are not important for design, so they are good at displaying and analyzing the data as appropriate visual elements (Pie Chart, Line Chart, Gauge, etc.) It's hard to have the result of a designed view with the WYSIWYG: What You See Is What You Get (WYSIWYG) effect that allows you to visualize the location of your equipment or intuitively identify the location of your farm's IOT devices and equipment. In addition, if the authoring tool is used without developing the visualization, the function and the expressive power of the control screen are limited because the component is provided by the authoring tool. In addition, it is difficult to map the visualization stage and data collection stage because they are not one integrated system. In addition, each visual element generally utilizes only the part of the data, not the whole. In this case, processing ability to filter only necessary data is required. If data processing capability is not available, a method of collecting already processed data using a query is used at the step of acquiring data. In this case, there are disadvantages such as an increase in the number of items of resources, duplicate data, and a large number of management points.

Finally, in the control screen view step, the control screen should be able to control the end device through commands such as clicking a visual element, manipulating a switch or selecting a list, or executing a specific query to control the situation. This should be extensible by allowing you to arbitrarily set the command's extension and accompanying actions. For example, a button must be able to start or stop a specific piece of equipment, take action if a failure occurs, and then terminate the failure. However, most data visualization tools do not consider the function of control. In the case of a tool that controls devices by interworking, it is limited to only compatible devices or provided in a list so that it does not cover the authoring of the control screen. In addition, the control screen view is limited by the increasing demand for mobile device proliferation, remote monitoring, and immediate response in the event of a failure in a static view with a display purpose, such as a factory dashboard or a dashboard in the field of infrastructure resource monitoring. It should be able to be used without this. In addition, even the same data should be created from various viewpoints according to the interests, and be able to be used for collaboration. Therefore, the control view should be accessible by various people according to the authority on various devices. However, the prior art does not provide such a function. In addition, the control monitoring field should be able to be connected to other systems such as ERP, MES, WMS, and be embedded in other systems, but there is a problem in that it cannot provide such a function.

One embodiment of the present invention provides a consistent method to easily manage and visualize data regardless of the source or format of the data, and to enable remote control even in a device or facility that does not have network communication capability, It is to provide a web-based integrated monitoring and monitoring system that enables the client to easily manage the process system and equipment through the web-based integrated system.

One embodiment of the present invention to provide a web-based monitoring monitoring integrated system that can reduce the load on the server by minimizing the request to the server.

In addition to the above object, the embodiment according to the present invention can be used to achieve other objects not specifically mentioned.

Control monitoring integrated system according to an embodiment of the present invention is a data providing unit, the data including a plurality of agents (Agent) for converting the data obtained from the data provider through the Action (Action) module from the resource (Resource) form (Resource) It may include a collection unit, a cloud server for storing and managing resources received from the data collection unit, and a data visualization tool for mapping and visualizing the resources received from the cloud server with visual elements.

The data visualization tool may include a control monitoring authoring tool capable of arbitrarily generating and arranging visual elements corresponding to each resource, a layout screen of final visual elements, additional update information check, and a viewer capable of device control.

The resource includes update time information, and the data collector may notify the cloud server only when a new change of the resource occurs and the resource value changes.

The resource may be managed according to a resource communication system (RCS).

Agents can be installed locally.

The integrated monitoring monitoring system according to an embodiment of the present invention may further include a board equipped with an agent that collects data from the data provider and transmits data to the server when the data provider does not have network communication capability. have.

The resource may further include key, data type, data, value, and name information.

The control monitoring authoring tool can arrange visual elements at precise positions by canvas-based X and Y coordinates, and may be configured in a desktop application format.

Web-based monitoring and monitoring integrated system according to an embodiment of the present invention is easy to collect and manage and visualize the data regardless of the source or format of the data, the client easily through the web-based integrated system from data collection to visualization and monitoring Process systems and equipment Can manage

Web-based control monitoring integrated system according to an embodiment of the present invention can reduce the load on the server by minimizing the request to the server.

1 is a schematic diagram of a web-based monitoring monitoring integrated system according to an embodiment of the present invention.
Figure 2 is a block diagram showing the operation sequence of the web-based monitoring monitoring integrated system according to an embodiment of the present invention.
FIG. 3 is a diagram illustrating an agent detailed component of a web-based monitoring and monitoring integration system according to an embodiment of the present invention. FIG.
4 is a diagram illustrating the detailed components of resources in the agent of the web-based monitoring and monitoring integrated system according to an embodiment of the present invention.
FIG. 5 is a diagram illustrating detailed components of an action within an agent of the web-based monitoring and monitoring integration system according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating detailed components of a task in an agent of a web-based monitoring and monitoring integration system according to an embodiment of the present invention.
7 is a flowchart illustrating a web-based integrated monitoring method according to an embodiment of the present invention.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described concretely with reference to drawings. In describing the embodiments of the present specification, when it is determined that a detailed description of a related well-known configuration or function may obscure the gist of the present specification, the detailed description thereof will be omitted.

When a component is said to be "connected" or "connected" to another component, it may be directly connected to or connected to that other component, but it may be understood that another component may be present in between. Should be. In addition, the content described as "include" a specific configuration in the present invention does not exclude a configuration other than the configuration, it means that additional configuration may be included in the scope of the technical idea of the present invention or the present invention.

In addition, the components shown in the embodiments of the present invention are shown independently to represent different characteristic functions, and do not mean that each component is made of separate hardware or one software unit. In other words, each component is included as a separate component for convenience of description, and at least two of the components may be combined to form one component, or one component may be divided into a plurality of components to perform a function. Integrated and separate embodiments of the components are also included within the scope of the present invention without departing from the spirit of the invention.

In addition, some of the components may not be essential components for performing essential functions in the present invention, but may be optional components for improving performance. The present invention can be implemented including only the components essential for implementing the essentials of the present invention except for the components used for improving performance, and the structure including only the essential components except for the optional components used for improving performance. Also included in the scope of the present invention.

1 is a schematic diagram of a web-based monitoring monitoring integrated system according to an embodiment of the present invention.

Figure 2 is a block diagram showing the operation sequence of the web-based monitoring monitoring integrated system according to an embodiment of the present invention.

1, the web-based control monitoring integrated system according to an embodiment of the present invention is a process system and equipment Data collector 100 for providing the relevant data, a data collector including a plurality of agents (Agent) for converting the data obtained from the data provider 100 through the Action module in the form of resources (Resource) 200, a cloud server 300 for storing and managing resources received from the data collection unit 200, and a data visualization tool 400 for mapping and visualizing the resources received from the cloud server 300 with visual elements. can do.

The data provider 100 may be a PC or a local server capable of transmitting data to the cloud server 300 through a network, and there is no TCP / IP network communication function for transmitting data to a remote server and performing remote control. It may be a sensor or equipment or a device / equipment capable of producing a. Referring to FIG. 1, in the case of an equipment or a facility that does not have a data transmission function but can produce data, a board (Board 1 or Board 2) to give a communication function between the data providing unit 100 and the data collecting unit 200. May be located. Here, the board is a circuit board for driving the agent to obtain or control the data of the sensor by serial communication and control the relay to control the power switch or switch and to send and receive resources to the cloud server 300.

The data collection unit 200 may include a plurality of agents. Each agent is a program that is installed and resides in a local area of a PC or server corresponding to a data source, and acquires data through a database, file, or device interface, processes it into a resource, and transmits and receives data to and from the cloud server 300. When the agent is configured through the board, the board can collect data or control the device by executing a script by implementing an action through the mounted agent, and convert the collected data into resources to the cloud server 300. Send and receive In addition, the agent resides in the local area, not in the public network section, so it can be exchanged in the security section without exposing equipment and DB connection information to the network section and processing it as a resource without exposing the format. have. In addition, the agent may simultaneously play the role of the data collection unit and the control unit. First, the role of the data collection unit accesses the DB through a registered Action Command to perform a query or to import data through the execution of a CLI script, and processes it into a resource in a consistent format to utilize it. The role of the control unit is to execute the execution command (Action) through the registered trigger processing module according to the resource value update to perform the equipment control by the method of database update, such as script execution.

FIG. 3 is a diagram illustrating an agent detailed component of a web-based monitoring and monitoring integration system according to an embodiment of the present invention.

Referring to FIG. 3, an agent may include detailed components of resources, actions, and tasks.

The resource is the result of converting the collected prototype data into a consistent format. At this time, the resource provides identification information of the source, name, and description in a form that can be easily used by the client, and includes the update time. All devices can always be synchronized with the latest data by the system.

Actions are a set of modular execution commands that perform data collection and control. They are a set of modular execution commands that can be extended, such as database actions, script actions, protocol actions, and HTTP API actions. When the action is executed, execution occurs according to each implementation defined in the action handler, and the execution result is reflected in the resource by the result processor or the caller is notified of the result. Here, the action handler is an implementation that operates when the defined action is executed. For example, in the case of an action handler of Oracle DB Action, it will be an operation that attempts a connection (connection) and executes a query based on the DB connection information defined in the action, and an action handler of Python Action. In this case, the action is to actually run the Python script. At this time, when the action handler is executed, it is executed with parameters.

A task is a component that corresponds to an agent's work when and when a command is performed, which occurs when a complex condition is met by periodic iterations, or by setting the condition of a particular resource, or by direct invocation. It is possible to define an execution rule to be executed or to define a plurality of actions to be performed.

4 is a diagram illustrating the detailed components of resources in the agent of the web-based monitoring and monitoring integrated system according to an embodiment of the present invention.

The resource may include a header part including a key and update time information, and a data part. When a new change of a resource occurs, the resource may be updated using only minimal overhead by exchanging only the resource header part.

Referring to FIG. 4, a resource may be identified by a key value uniquely assigned in a system in a key and value structure, and a key, data type, data, and user may be identified. At least one of a given Name and an update time may be included. Specifically, the resource includes a header portion including a key and an update time, and a namespace including data type, data, value, and data schema information necessary for data interpretation, and identified by a user. It may further include a Name and a Description necessary to do so.

First, the key is automatically assigned by the system to a unique value that identifies the resource. Data type means the data type. For example, it may be a number, a letter, a collection, an object, or the like. Data corresponds to actual data, and objects and collections are managed in Json format. Namespace information can be used to select the parser of the object. Names and descriptions are names given by the user for easy identification when the user authors the visualization. Here, the parser is an analyzer that analyzes and objectifies the format expressed in Json. This is to use extended data types in addition to known value types or data types. If you define type information at a specific address and specify a namespace, you can object to that data type. That is, information about which object to object is obtained from the namespace. In addition, the update time is synchronized by the RCS (Resource Communication System) system so that devices that subscribe to the resource can keep the resource up to date.

FIG. 5 is a diagram illustrating detailed components of an action within an agent of a web-based integrated monitoring system according to an embodiment of the present invention.

Referring to FIG. 5, an action may include detailed components of a parameter, an action processor module, and a result processing module.

A parameter is a variable that is passed to the execution of the action. The parameter may be defined by the caller, and the property value of a visual element or the value of a specific resource may be used. The result processing module is an automated function for processing the result values received from the action processing module in a consistent manner, and can update specific resources with the result values or return them to the caller. The action handler module executes the defined command using parameters, and passes it to the result processing module after execution. In addition, the action handler module is a module that can be extended by a user by providing a standard interface. For example, the action handler module may include one or more of an Ms-sql, an Oracle action, a Modbus action, a text message action, and a Pythion script action. As such, adding drivers allows you to push the limits of data acquisition and control just as new devices can be used as drivers are added.

FIG. 6 is a diagram illustrating the detailed components of a task in an agent of a web-based monitoring and monitoring integrated system according to an embodiment of the present invention.

Referring to FIG. 6, the task may include detailed components of the start setting unit and the execution list unit. The start setting unit is a part which can set when a corresponding task is started, and can be started by setting through a scheduler, a trigger condition for executing when a condition of a specific resource is satisfied, and a user call. The execution list section lists the execution order to execute the registered execution order in order when the task is executed. At this time, execution can be stopped or skipped and progressed by the continuous method among the result values of the previous action.

In addition, each agent may obtain data through an action that is an execution command. An action can be composed of a common parameter constructing unit and a result processing unit. The result processing unit processes the result processed by the action handler, and reflects the result to the resource or returns it to the calling unit. do. In this way, as a driver is added, a new device can be used, and by adding an action module, an extended end point can be provided that is modularized to expand the support area for data acquisition and can be customized. The parameter configuration unit of an action can use a resource value or receive a constant value when the action is executed. The logic can be processed by an action handler and the result processing module can update a specific resource. The action handler is the logic that executes when the action is executed, and the implementation that actually takes place when the action is called.

In more detail, the data obtained by the action command in each agent may be converted into resources designated by the result processing module. When the resource is updated, update information is sent to the cloud server 300, and the cloud server 300 may operate by requesting resource synchronization by notifying the resource subscriber of the change.

In the present specification, a set of technologies that are collected and supplied by the cloud server 300 after being converted into a resource in the local area and synchronized with a client subscribing to the resource is referred to as a resource communication system (RCS). The RCS defines API specifications and resource configuration for registering, changing, removing, subscribing to, and notifying resources with the cloud server 300, and simplifies the method of data exchange between devices to one channel and is used for monitoring monitoring. It can be used in systems for lifecycle management and collection / supply of data.

The agent collects source data and converts it into a resource, the cloud server 300 is responsible for collecting / providing the resources, and the viewer 420 visualizes the resource, and when the value of the resource is changed when the control is made, the RCS By the resource synchronization by the resource change agent to be informed of the resource change to the agent, the agent can control the end process and the device in such a manner to perform the action according to the task specified by the set resource trigger.

In other words, a single path for data synchronization, visualization, and control by the RCS can be used to simplify the problem and build an integrated system.

All of the agent's configuration information is stored in the cloud server 300, so it is easy to restore and replace when the agent is replaced, and easy to replicate when configuring a similar environment.

In the case of the existing monitoring / monitoring system having a general client's request / server response structure, even if there is no actual data change, the client continuously sends a request to the server to see if the data has changed. There is a problem that can cause server load.

Resource of the web-based monitoring and monitoring integrated system according to an embodiment of the present invention includes the update time information, the data server 200 in the cloud server 300 only when a new value of the resource changes the resource value changes ), Which has the effect of reducing server load.

The cloud server 300 collects and supplies resources from agents of a plurality of different devices. The cloud server 300 implements an API for registering, changing, or subscribing a resource according to an RCS standard, and managing a life cycle of the resource. In addition, the cloud server 300 can manage the cumulative number of resources set for the visual elements, such as charts and tables for continuous monitoring data management, and manages the client to subscribe the resources Notify when a resource has been modified.

The data visualization tool 400 is a control monitoring authoring tool 410 that can arbitrarily generate and arrange visual elements corresponding to each resource, edit the properties of the visual elements, and design a layout screen of the final visual elements, and additional update information. It may include a viewer 420 that can be confirmed, the data control.

The visual element is a component of the control screen, which can be a chart, a gauge, etc. for intuitively knowing numerical values, and can be a label, a text indicator such as a seven segment, a table and a list for displaying a collection, and the like. In addition, there are elements such as buttons, switches, and sliders that can interact with the user, and components for designing using images and shapes can be included. The visual elements are modular, and can configure web components for web display. In the monitoring and monitoring authoring tool 410, they are named as components and provide standard interfaces to customize the information, templates, property lists, and property editors of components. You can do it so that you can expand your expression.

The control monitoring authoring tool 410 may place visual elements at precise positions by canvas-based X and Y coordinates, and may be configured in a desktop application format. In addition, the control monitoring authoring tool 410 may be displayed by maintaining a ratio even if the resolution is different from the resolution produced by supporting the zoom (Zoom) function. In addition, it is possible to produce a beautiful design with various attribute values of visual elements and components for design such as line, shape and image. In addition, the authored screen can be finally output based on the web. Furthermore, using standard HTML5, it operates in the latest browser without installing a separate library and can be integrated by being embedded through WebView of other systems based on the web. In addition, web-based authoring tools generally provide designers on the web, and designers need highly scalable professional tools such as supporting and debugging various view panels. Implementing them on the web has many limitations on performance and technical support. This will follow. The control monitoring authoring tool 410 of the web-based control monitoring integrated system according to an embodiment of the present invention may be provided in the form of a desktop application, and provides a powerful tool and an easy design method of a drag drop method such as PowerPoint. Can provide. You can also configure the final output to be rendered on the web.

 The control monitoring authoring tool 410 of the web-based control monitoring integrated system according to an embodiment of the present invention may be a structure in which a component can be directly included by only observing a predetermined interface by modularizing the component. You can use standard web component technologies and provide an interface that allows you to describe wizards, data mappings, and events for use in designers. The visual element may be a structure that is gradually expandable and open to expansion to have abundant expressive power without restriction. A component of a component may be composed of component configuration information, a web component template, a component property, and a component event part. In addition, it may have an abstract class on the interface corresponding to each component, all components can be configured on this unified basis.

The visual element may be displayed by taking only partial data of the resource. At this time, the resource processing ability of the viewer (client) can be minimized, thus minimizing the resources configured by the server, minimizing duplicate data, and minimizing requests, thereby improving performance.

When mapping resources to visual elements, you can configure filters to specify a larger category of resources. For example, a large number of resources, such as temperature A, temperature B, temperature C, etc., are not necessary, and the data through the filter can be specified in the entire resource called temperature status. As a result, the load of the cloud server 300 can be reduced by minimizing the request, and the management point can be reduced and simplified.

Specifically, when a resource is updated, a filter can be run on the visual element that you want to update to specify the row and set the DataPath to specify the column.

Web-based control monitoring integrated system according to an embodiment of the present invention can operate under the service base for collaboration. Specifically, you can authenticate with OAuth, and organize your project and team. You can share the data collected by the agent in units of configured projects. You can author and control multiple views in one project. The entire system can be configured as a data visualization platform that supports collaboration as a whole.

Figure 2 is a block diagram showing the operation sequence of the web-based monitoring monitoring integrated system according to an embodiment of the present invention.

Referring to FIG. 2, the agent converts the collected data into a resource form and delivers the data to the cloud server 300. Next, the cloud server 300 cumulatively manages the resources, and serves to provide resources when requested by the control monitoring authoring tool 410 or the viewer 420, and notifies the subscriber of the changes when the resource changes. Next, the viewer 420 requests a resource to the cloud server 300 for updating the visual element, and when the cloud server 300 is notified of the resource change, changes the resource.

7 is a flowchart illustrating a web-based integrated monitoring method according to an embodiment of the present invention.

Hereinafter, a web-based integrated monitoring method according to an embodiment of the present invention will be described with reference to FIGS. 2 and 7.

Web-based integrated control monitoring method according to an embodiment of the present invention is a data collection step of collecting the initial data in the data providing unit (S100), the data collected in the data collection step of the agent of the data collection unit 200 Resource generation step (S200) to receive from the (Agent) is converted to the resource (Resource) format, resource mapping step (S400) for mapping the resources generated in the resource generation step with the corresponding visual element, the visual element is finished resource mapping It may include a viewer display step (S500) for displaying on the viewer screen according to the convenience of the client.

Web-based integrated control monitoring method according to an embodiment of the present invention, after the resource generation step (S200), the control visualization screen authoring step (S300) for creating and designing visual elements using the control monitoring authoring tool 410 It may further include.

The resource is managed according to a resource communication system (RCS), and the resource may include update time information. In addition, the data collection unit 200 may notify the cloud server 300 only when a new change of resource occurs and the resource value is changed. In this case, since the data collector 200 notifies the cloud server 300 only when a new change of the resource occurs and the resource value is changed, the cloud server 300 load can be reduced. .

First, create a resource called "a temperature" ("data type" is a number). Next, the command "Get a temperature" is configured. Specifically, construct a Python script action and configure the execution result to "update a temperature resource". Next, configure the task to continually retrieve its resources. Specifically, a task called "Temperature Update" is created, and the execution condition includes the corresponding action configured in the execution list 2 at the time of 'Agent start' and 'Every 5 seconds'. As the task is executed, the set execution commands are executed in order and the corresponding resources are updated. The resources are transferred to the cloud server through the synchronization of the RCS, and the server accumulates and manages the data by setting the cumulative number of times, which is the RCS specification of the resource, and removes the old resources out of the management scope. In addition, the server notifies the resource change information while managing the client (viewer) who has requested the use of the resource (subscription).

Next, the user designs the image and shape through the control monitoring authoring tool, and authors the screen by arranging various visual elements such as charts, gauges, and tables. Specifically, a 'gauge' visual element is placed on the screen to visualize a temperature. Next, map resources to visual elements. Specifically, the resource browser displays resource names and sources that the user can identify. When using only some of the resources, you can filter and specify the value of the resource. It provides a standard way of mapping resources to visual elements, and wizards are provided by authoring tools when special mapping settings such as charts and tables are required. Specifically, map the temperature resource a to the gauge. Next, it is displayed on the control monitoring screen (viewer). The visual element makes a data request to the server and the server notifies the client (viewer) that subscribes to the resource when the data changes. When a temperature is changed by RCS, a temperature change notification is received from the server, and the value of the gauge, which is a visual element, is updated by the resource synchronization technology.

Hereinafter, the content overlapping with the above description will be omitted.

In the above-described embodiment, the methods are described based on a flowchart as a series of steps or blocks, but the present invention is not limited to the order of steps, and any steps may occur in a different order or at the same time than the other steps described above. have. Also, one of ordinary skill in the art appreciates that the steps shown in the flowcharts are not exclusive, that other steps may be included, or that one or more steps in the flowcharts may be deleted without affecting the scope of the present invention. I can understand.

The above-described embodiments include examples of various aspects. While not all possible combinations may be described to represent the various aspects, one of ordinary skill in the art will recognize that other combinations are possible. Accordingly, the invention is intended to embrace all other replacements, modifications and variations that fall within the scope of the following claims.

Claims (5)

Data Provider,
A data collecting unit including a plurality of agents converting data obtained from the data providing unit through an action module into a resource form;
Cloud server for storing and managing the resources received from the data collection unit,
It includes a data visualization tool for visualizing by mapping the resources received from the cloud server with the visual element,
The data visualization tool includes a control monitoring authoring tool capable of arbitrarily generating and arranging visual elements corresponding to each resource, a layout screen of final visual elements, additional update information confirmation, and a viewer capable of data control.
And the resource includes update time information, and the data collection unit notifies the cloud server only when a new change of the resource occurs and the resource value is changed. In claim 1,
The agent is installed in the local area,
The control monitoring integrated system may further include a board for transmitting data to the agent installed in a local area by collecting data from the data providing unit when the data providing unit has no network communication capability. Monitoring integrated system. In claim 2,
The resource further includes a key, data type, data, value, and name information. In claim 3,
The control monitoring authoring tool is a web-based control monitoring integrated system that can place the visual elements in the correct position by the canvas (X, Y) coordinates, and is configured in a desktop application format. In claim 4,
And the resource is managed according to a resource communication system (RCS).

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