KR20230146845A - Hierarchical smart tag-based object processing apparatus and method - Google Patents

Abstract

The present invention relates to a hierarchical smart tag-based object processing device and method, wherein the device includes an object creation unit that creates an object, hierarchically assigns smart tags to the object to create a hierarchical path for the object, and The smart tag includes a smart tag allocator that receives a tag name for a designated object and is created by setting search conditions for the designated object, and provides the hierarchical path as a breadcrumb in the process of processing the object. Includes a breadcrumb processing unit.

Description

Hierarchical smart tag-based object processing device and method {HIERARCHICAL SMART TAG-BASED OBJECT PROCESSING APPARATUS AND METHOD}

The present invention relates to object processing technology, and more specifically, to a hierarchical smart tag-based object processing device and method that can provide efficient search and management functions for objects through hierarchically assigned smart tags. .

In general, an Internet messenger corresponds to an application that transmits messages containing text or graphics between users, and may be implemented as a chat room in which multiple users participate. In one embodiment, the Internet messenger may include a mobile messenger executed in a mobile environment (e.g., a mobile phone) and may include, for example, KakaoTalk, Line, WeChat, Facebook Messenger, etc. In addition, such Internet messengers are increasingly being used in a variety of ways in the management and progress of work.

A Kanban board is one of the tools that can be used to implement Kanban for managing tasks at a personal or organizational level. In addition, the Kanban board is a board that visualizes the work stages and sub-tasks of each work stage by listing them on a flat surface. The Kanban board lists each step of the entire process of a high-level task in one direction and uses cards to express work items. The cards used on the kanban board can be referred to as kanban cards. For example, the kanban card can be moved from left to right for each task step to indicate the progress of the task.

Here, Kanban (看板) is one of the software development processes and is a concept derived from a development method that allows products to be released on time without placing excessive load on developers.

Korean Patent Publication No. 10-2017-0040928 (2017.04.14)

An embodiment of the present invention seeks to provide an object processing device and method based on hierarchical smart tags that can provide efficient search and management functions for objects through hierarchically assigned smart tags.

Among embodiments, a hierarchical smart tag-based object processing device includes an object creation unit that creates an object, hierarchically assigns a smart tag to the object to create a hierarchical path for the object, and the smart tag is a designated target. It includes a smart tag allocation unit that receives a tag name for the target and is created by setting search conditions for the designated object, and a breadcrumb processing unit that provides the hierarchical path as a breadcrumb in the process of processing the object. .

The object creation unit may create the object as a business unit.

The object creation unit is the work unit and can create a work project, work note, work object, work chat room, kanban card, or kanban board.

The smart tag allocator may configure the search conditions with search keywords and search operators.

The smart tag allocator may hierarchically assign a second smart tag to a first smart tag by including other smart tags that do not have a mutual inclusion relationship in the smart tag.

The smart tag allocator can set the user's access rights to the smart tag and hide the object associated with the smart tag from users who do not have access rights.

When a search using the smart tag is performed, the smart tag allocator may detect a change in the corresponding object and notify the change through the breadcrumb.

If there are multiple hierarchical paths for the object, the breadcrumb processing unit may provide each as an independent, separate breadcrumb.

When one of the independent and separate breadcrumbs is selected, the breadcrumb processing unit can provide all smart tags associated with the smart tag in the selected breadcrumb as a tree structure.

The breadcrumb processing unit may allow changes to tag names or search conditions for smart tags in the breadcrumb.

The breadcrumb processing unit may provide object status for all objects associated with smart tags in the breadcrumb.

Among embodiments, a hierarchical smart tag-based object processing device includes an object creation unit that creates an object, a smart tag allocator that assigns a first smart tag to the object, and a hierarchical smart tag that assigns a second smart tag to the first smart tag. It includes a hierarchical path creation unit that generates a hierarchical path for the object by allocating the object, and a breadcrumb processing unit that provides the hierarchical path as a breadcrumb in the process of processing the object, wherein the first And second smart tags can be created by receiving a tag name for a designated object and setting search conditions for the designated object.

Among embodiments, a hierarchical smart tag-based object processing method includes an object creation step of creating an object, hierarchically assigning a smart tag to the object to create a hierarchical path for the object, and the smart tag is a designated target. It includes a smart tag assignment step that is created by inputting a tag name for the target and setting search conditions for the designated object, and a breadcrumb processing step that provides the hierarchical path as a breadcrumb in the process of processing the object. do.

The smart tag allocation step may include configuring the search conditions with search keywords and search operators.

The smart tag allocation step may include the step of hierarchically assigning a second smart tag to a first smart tag by including other smart tags with which a mutual inclusion relationship is not established in the smart tag.

The smart tag allocation step may include setting the user's access rights to the smart tag and hiding the object associated with the smart tag from users who do not have access rights.

The smart tag allocation step may include detecting a change in the corresponding object when a search using the smart tag is performed and notifying the change through the breadcrumb.

The breadcrumb processing step may include providing each hierarchical path to the object as an independent separate breadcrumb if there are multiple hierarchical paths.

The disclosed technology can have the following effects. However, since it does not mean that a specific embodiment must include all of the following effects or only the following effects, the scope of rights of the disclosed technology should not be understood as being limited thereby.

The hierarchical smart tag-based object processing apparatus and method according to the present invention can provide efficient search and management functions for objects through hierarchically assigned smart tags.

In particular, the hierarchical path for the object is provided as a breadcrumb, making it possible to easily understand the object processing process.

1 is a diagram explaining an object processing system according to the present invention.
FIG. 2 is a diagram explaining the system configuration of the object processing device in FIG. 1.
FIG. 3 is a diagram explaining the functional configuration of the object processing device in FIG. 1.
Figure 4 is a flowchart explaining a hierarchical smart tag-based object processing method according to the present invention.
Figure 5 is a diagram explaining the configuration of a smart tag according to the present invention.
Figures 6 and 7 are diagrams illustrating an embodiment of the smart tag attachment and search process according to the present invention.
Figures 8 and 9 are diagrams illustrating an embodiment of a process for providing search results of a smart tag according to the present invention.

Since the description of the present invention is only an example for structural or functional explanation, the scope of the present invention should not be construed as limited by the examples described in the text. In other words, since the embodiments can be modified in various ways and can have various forms, the scope of rights of the present invention should be understood to include equivalents that can realize the technical idea. In addition, the purpose or effect presented in the present invention does not mean that a specific embodiment must include all or only such effects, so the scope of the present invention should not be understood as limited thereby.

Meanwhile, the meaning of the terms described in this application should be understood as follows.

Terms such as “first” and “second” are used to distinguish one component from another component, and the scope of rights should not be limited by these terms. For example, a first component may be named a second component, and similarly, the second component may also be named a first component.

When a component is referred to as being “connected” to another component, it should be understood that it may be directly connected to the other component, but that other components may exist in between. On the other hand, when a component is referred to as being “directly connected” to another component, it should be understood that there are no other components in between. Meanwhile, other expressions that describe the relationship between components, such as "between" and "immediately between" or "neighboring" and "directly neighboring" should be interpreted similarly.

Singular expressions should be understood to include plural expressions unless the context clearly indicates otherwise, and terms such as “comprise” or “have” refer to implemented features, numbers, steps, operations, components, parts, or them. It is intended to specify the existence of a combination, and should be understood as not excluding in advance the possibility of the presence or addition of one or more other features, numbers, steps, operations, components, parts, or combinations thereof.

For each step, identification codes (e.g., a, b, c, etc.) are used for convenience of explanation. The identification codes do not explain the order of each step, and each step clearly follows a specific order in context. Unless specified, events may occur differently from the specified order. That is, each step may occur in the same order as specified, may be performed substantially simultaneously, or may be performed in the opposite order.

The present invention can be implemented as computer-readable code on a computer-readable recording medium, and the computer-readable recording medium includes all types of recording devices that store data that can be read by a computer system. . Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, and optical data storage devices. Additionally, the computer-readable recording medium can be distributed across computer systems connected to a network, so that computer-readable code can be stored and executed in a distributed manner.

All terms used herein, unless otherwise defined, have the same meaning as commonly understood by a person of ordinary skill in the field to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as consistent with the meaning they have in the context of the related technology, and cannot be interpreted as having an ideal or excessively formal meaning unless clearly defined in the present application.

1 is a diagram explaining an object processing system according to the present invention.

Referring to FIG. 1 , the object processing system 100 may include a plurality of user terminals 110 and an object processing device 130.

Multiple users may be included in one or more user groups. One or more user groups may be referred to as a first user group, a second user group, etc. One user may be included in one or more user groups.

The first user terminal 110a may correspond to the first user's terminal, the second user terminal 110b may correspond to the second user's terminal, and the third user terminal 110c may correspond to the third user's terminal. .

Here, the first to third users may correspond to work participants who participate in a work project and perform and process related work. For example, for a specific task of a business project, a specific user among the first to third users may be a task creator or task instructor, and other users may be task processors who directly process the task. Additionally, task participants other than the task creator or task instructor and task processor may be classified as task related.

A work project in which a first user to a third user participates may be included in the overall project, and the entire project may be divided into predetermined stages. The entire project may include or exist as dependents on multiple work projects. Additionally, in each work project, work notes can be recorded and stored according to the work progress stage, and a work chat room in which work participants related to the work participate can be created in the work note. Work participants can conduct work-related conversations through work chat rooms, and create and share work tasks as needed.

For example, the work progress stage of the entire project can be defined as in progress, confirming, supplementing, supplementation completed, etc. according to the PDCA cycle. Here, the PDCA cycle may correspond to a systematic and efficient work management technique to increase work performance and performance.

More specifically, P may correspond to the establishment of a plan, that is, the step of setting the goal of a work project and establishing specific strategies and action plans for its realization. D may correspond to the performance of work (do), that is, the step of actually performing and processing work in accordance with regulations, guidelines, standards, etc., based on the plan established and corresponding to the records of work notes. C is check, that is, it corresponds to the operation of the work chat room and corresponds to the step of checking the work performance results of step D and then analyzing and evaluating them to check for differences from the initially set goal and find areas to improve or correct. You can. Lastly, A carries out the necessary actions for improvement and supplementation, such as modifying the existing work performance results or reprocessing the work contents by reflecting the problems and improvements identified in the previous step C. It may correspond to the stage of doing so.

The object processing device 130 may correspond to a computing device that can be connected to at least one user terminal 110 through a network. The object processing device 130 may manage at least one user group in which other users associated with one user are members, that is, work participants.

In one embodiment, the object processing device 130 may operate in conjunction with the user terminal 110 through an agent installed on the user terminal 110. Here, the agent is an application or program that is installed and operates on the user terminal 110 and allows the user terminal 110 and the object processing device 130 to interact with each other under the approval of the user terminal 110. You can.

The user terminal 110 corresponds to a computing device that can be connected to the object processing device 130 through a network, and can be implemented as, for example, a desktop, laptop, tablet PC, or smartphone.

In one embodiment, the user terminal 110 may be implemented as a mobile terminal, and in this case, the user terminal 110 may be connected to the object processing device 130 through cellular communication or Wi-Fi communication. In another embodiment, the user terminal 110 may be implemented as a desktop and may be connected to the object processing device 130 via the Internet.

FIG. 2 is a diagram explaining the system configuration of the object processing device in FIG. 1.

Referring to FIG. 2 , the object processing device 130 may include a processor 210, a memory 230, a user input/output unit 250, and a network input/output unit 270.

The processor 210 can execute an object processing procedure according to an embodiment of the present invention, and manage the memory 230 that is read or written in this process, and the volatile memory and non-volatile memory in the memory 230. You can schedule synchronization times between

The processor 210 can control the overall operation of the object processing device 130 and is electrically connected to the memory 230, the user input/output unit 250, and the network input/output unit 270 to control data flow between them. You can. For example, the processor 210 may be implemented as a central processing unit (CPU) of the object processing device 130. The processor 210 can be logically defined as modules that perform various operations, and while each module performs independent operations, they can be organically combined with each other to process specific operations according to the present invention.

The memory 230 may be implemented including an auxiliary memory device and a main memory device. The auxiliary memory device is implemented as a non-volatile memory and can store all data required for the object processing device 130, and may include a solid state disk (SSD) or a hard disk drive (HDD). The main memory device may be implemented as volatile memory and may include RAM (Random Access Memory).

The user input/output unit 250 may include an environment for receiving user input and an environment for outputting specific information to the user. For example, the user input/output unit 250 may include input devices such as a mouse, trackball, touch pad, graphic tablet, scanner, touch screen, keyboard, and pointing device, and output devices such as a monitor and touch screen. In one embodiment, the user input/output unit 250 may correspond to a computing device connected through a remote connection, and in such case, the object processing device 130 may function as a server.

The network input/output unit 270 may provide a communication environment for connecting to the user terminal 110 through a network. For example, the network input/output unit 270 may include an adapter for communication such as a local area network (LAN), a metropolitan area network (MAN), a wide area network (WAN), and a value added network (VAN). Additionally, the network input/output unit 270 may be implemented to provide short-range communication functions such as WiFi and Bluetooth or wireless communication functions of 4G or higher for wireless transmission of data.

FIG. 3 is a diagram explaining the functional configuration of the object processing device in FIG. 1.

Referring to FIG. 3 , the object processing device 130 may include an object creation unit 310, a smart tag allocation unit 330, a breadcrumb processing unit 350, and a control unit 370.

The object creation unit 310 may create an object. The object creation unit 310 may create an object as a business unit. A work unit may correspond to a unit object according to the work progress stage. The object creation unit 310 is a work unit and can create a work project, work note, work object, work chat room, kanban card, or kanban board.

In one embodiment, the object creation unit 310 may create at least one work project that is managed within the entire project and progresses independently. At this time, each business project can be managed according to independent work progress stages, and the entire project can be implemented to manage the work progress stages of each business project in an integrated manner. The object creation unit 310 may create a work note containing work instructions and work processing content and a work chat room based on user interaction.

Additionally, the object creation unit 310 may create a work object that implements a work processing flow through a plurality of heterogeneous work units having a dependent relationship. Here, a work object can be created including various work units that are created and processed in relation to work within the entire project, and can be implemented to provide various management functions for work management. For example, a work object can be created in response to a work project, and a work processing flow corresponding to work progress within the work project can be actualized. In other words, a work processing flow can be formed through the connection relationship between various work units created as work progresses. The object creation unit 310 can create a Kanban card corresponding to a business project on the Kanban board.

Work units can be classified into different types according to work projects, work notes, work objects, work chat rooms, kanban cards, or kanban boards, and can be processed and managed for each type. The object processing device 130 may create and provide a dedicated container to manage each type of work unit. In other words, work units of the same type can be inserted and managed in the same container, and movement between containers can also be performed through interconnected link information.

Priorities regarding creation can be set between work units. For example, within an overall project, a work project may be created as the highest priority. After the creation of a work project, any one of work notes, work objects, work chat rooms, and kanban cards or kanban boards may be created as a subordinate. Additionally, after the creation of a business note, any one of a business object, a business chat room, a Kanban card, or a Kanban board may be created as a subordinate. Additionally, after the creation of the work chat room, the Kanban card or Kanban board may be created as a subordinate.

The smart tag allocator 330 can hierarchically assign smart tags to objects and create a hierarchical path for the objects. Smart tags can be created by receiving the tag name for the designated target and setting search conditions for the designated target. In other words, a smart tag may be composed of a tag name and search conditions. Here, a smart tag may correspond to a tag independently attached to each designated object, and multiple smart tags may be attached to one designated object.

In one embodiment, the smart tag allocator 330 may provide an interface for creating a smart tag, and a user may create a smart tag by entering a tag name or search condition through the interface. Here, the smart tag allocator 330 can manually attach the generated smart tag to a designated target according to the user's selection, and automatically attach it to the designated target that satisfies the search conditions.

In one embodiment, the smart tag allocator 330 detects the creation of a work unit and if a higher type of work unit linked to the work unit exists, the smart tag allocator 330 assigns a smart tag based on the identification information of the user associated with the creation of the work unit. It can be created and attached to a higher type of business unit. For example, when a work note is created in a work project by user A, a smart tag corresponding to user A's name may be created and attached to the work project. Work units with smart tags attached can be easily searched through the smart tag. Additionally, when multiple work notes are created within the same work project, a different smart tag can be automatically created for each user and attached to the work project. As a result, this can achieve the effect of automatically creating and attaching smart tags searchable by creator name as many as the number of creators.

In other words, when a smart tag is first created according to the creation of a work unit, the smart tag can be created with the name of the original creator as the tag name. Afterwards, search conditions for the work unit can be added to the smart tag. At this time, the smart tag allocator 330 may initiate a search operation for the smart tag updated with the addition of the search condition, and assign the smart tag to work units that meet the search conditions according to the search of the smart tag. Can be attached automatically. If the searched work unit already has the same smart tag attached, an operation to update the smart tag can be performed, and if the smart tag is not attached to the searched work unit, the smart tag can be additionally attached. .

In one embodiment, the smart tag allocator 330 can check the uniqueness of the tag name, configure search conditions with search keywords and search operators, and set the user's access rights to the smart tag. When a tag name is input by a user, the smart tag allocator 330 can detect whether a smart tag identical to the tag name exists. If the corresponding tag name already exists, the smart tag allocator 330 may request the user to input a new tag name. If the tag name is determined to be unique, the smart tag allocator 330 may create a smart tag with the corresponding tag name and request input for search conditions for the corresponding smart tag. At this time, the search condition may consist of a search keyword and a search operator. Search keywords may basically include tag names, but may not necessarily be limited to this. The search condition may be composed of a combination of at least one search keyword and a search operator related thereto and expressed as a predetermined search expression.

For example, in the case of a search condition such as <content='quality'>, it may correspond to a condition for searching work units containing the word 'quality', and 'quality' may correspond to a search keyword. In the case of a search condition such as <Content='Quality'+'Performance'>, it may correspond to a search condition for work units containing the words 'quality' or 'performance'.

In one embodiment, the smart tag allocator 330 may hierarchically assign the second smart tag to the first smart tag by including other smart tags that do not have a mutual inclusion relationship in the smart tag. Here, the smart tag allocator 330 allocates a first smart tag to an object, hierarchically assigns a second smart tag to the first smart tag, includes the first smart tag in the second smart tag, and assigns the first smart tag to the first smart tag. By including objects in smart tags, a hierarchical path (second smart tag/first smart tag/object) for the object can be created. The first and second smart tags can be created by receiving a tag name for a designated target and setting search conditions for the designated target. In other words, the search conditions of a smart tag include other smart tags, so smart tags can be hierarchically assigned to an object, and a hierarchical path for the object can be created. For example, by creating an object and creating a first smart tag associated with the object, the first smart tag is assigned to the object, and by creating a second smart tag associated with the first smart tag, the first smart tag is assigned a second smart tag. If is assigned - this means that the object is included in the search conditions of the first smart tag and the first smart tag is included in the search conditions of the second smart tag - the user selects the second smart tag to A search can be started using the search conditions of the smart tag, and at this time, the search results may include a search result related to the first smart tag.

In one embodiment, the smart tag allocator 330 may implement a hierarchical tree structure connected between smart tags by including other smart tags in the search conditions of the smart tag. When a change occurs due to the creation or deletion of an object associated with a smart tag, the smart tag allocation unit 330 reallocates the smart tag accordingly and re-associates the tree structure between the smart tags to establish a hierarchical path for the object. You can change it.

Meanwhile, when the search conditions of the first smart tag include the second smart tag and the search conditions of the second smart tag include the first smart tag, a mutual inclusion relationship can be established between the first and second smart tags. there is. The smart tag allocator 330 can prevent a search operation from being performed cyclically according to the mutual inclusion relationship by including only other smart tags with which the mutual inclusion relationship does not exist in the smart tag as search conditions.

Additionally, the smart tag allocator 330 can set the user's access rights to the smart tag and hide objects associated with the smart tag from users who do not have access rights. In other words, the smart tag allocator 330 allows only users with access rights to use the corresponding smart tag or access related functions, and the access rights can be basically set by the user during the creation process of the smart tag. there is. The access rights of the smart tag can be modified by the authorized user during the subsequent use process, and can also be set automatically when certain setting conditions are met. The smart tag allocator 330 can allow the user to perform a search through the smart tag if the user has access rights to the search conditions of a specific smart tag. Otherwise, if the user does not have access rights, the user can perform a search through the smart tag. Even if you select the smart tag, the object associated with the smart tag may be hidden and searchable may not be possible.

In one embodiment, the smart tag allocator 330 may detect a change in the corresponding object when a search using a smart tag is performed and notify the change through breadcrumb. The smart tag allocator 330 can notify changes to the corresponding object through the smart tag in the breadcrumb. Breadcrumbs can provide hierarchical paths to objects. For example, when a user initiates a search operation through a smart tag, changes to the object associated with the smart tag can be detected while searching the hierarchical path for the object associated with the smart tag. If an object for which a change has been detected according to a search through a smart tag exists, the smart tag allocator 330 may notify the user by visualizing and displaying a smart tag for the hierarchical path to which the object is dependent.

For example, when a user searches for a work project through a smart tag, the smart tag allocator 330 can detect work notes that have recently changed among the work notes associated with the smart tag, and may detect the searched work project. You can display smart tags associated with the relevant work notes by highlighting them. Accordingly, the user can check the work project including the smart tag highlighted on the search results screen and indirectly recognize that a work note that has recently changed exists among the work notes in the work project. Meanwhile, the highlighting operation may correspond to an operation that emphasizes at least one of shape, shape, and color among the smart tag visualization methods.

The breadcrumb processing unit 350 may provide a hierarchical path as a breadcrumb in the object processing process. If there are multiple hierarchical paths to an object, the breadcrumb processing unit 350 may provide each as an independent and separate breadcrumb. A breadcrumb can correspond to a visual representation of a hierarchical path to search results associated with a smart tag. For example, if the object corresponds to a kanban card created in response to a business project on the kanban board and two smart tags are hierarchically assigned to the object, the breadcrumb processing unit 350 displays 'kanban board/smart tag 1/ Breadcrumbs such as ‘Smart Tag 2/Kanban Card’ can display the hierarchical path of the object. When one of the independent and separate breadcrumbs is selected, the breadcrumb processing unit 350 can provide all smart tags associated with the smart tag in the selected breadcrumb as a tree structure. Here, the breadcrumb processing unit 350 updates the corresponding tree structure every time the user selects one of several breadcrumbs to know the hierarchical structure of all smart tags to which the smart tags in the selected breadcrumb belong.

The breadcrumb processing unit 350 can allow changes to tag names or search conditions for smart tags in the breadcrumb. In one embodiment, when a breadcrumb is selected by the user, the breadcrumb processing unit 350 displays a dashboard screen including tag names and search conditions for smart tags in the selected breadcrumb on the user terminal 110 to enable the user to use the breadcrumb. You can edit the tag name or search conditions.

Additionally, the breadcrumb processing unit 350 can provide object status for all objects associated with smart tags in the breadcrumb. In one embodiment, when an object is created as a business unit, the object processing process may implement a PDCA (Plan Do Check Act) business processing flow using business projects, business notes, business chat rooms, and business tasks. A work project is created in response to P (Plan) in the PDCA work processing flow, a work note can be associated with D (Do), a work chat room can be associated with C (Check), and a work task can be associated with A (Act). can be responded to. The object processing process can be initiated according to the creation of a business project within the entire project, and each task can be processed based on the creation time of business notes, business chat rooms, and business tasks within the business project. By defining the precedence relationship, you can implement a work processing flow corresponding to the work project. The breadcrumb processing unit 350 can provide object states as D (Do), C (Check), and A (Act). In one embodiment, the breadcrumb processing unit 350 processes P (Plan) corresponding to the search result of the smart tag and D (Do), C (Check), and A (Act) connected to the P (Plan) as object states. can be provided, and related statistics can be provided.

The control unit 370 controls the overall operation of the object processing device 130 and manages the control flow or data flow between the object creation unit 310, the smart tag allocation unit 330, and the breadcrumb processing unit 350. .

Figure 4 is a flowchart explaining a hierarchical smart tag-based object processing method according to the present invention.

Referring to FIG. 4, the object processing device 130 may create an object through the object creation unit 310 (step S410).

The object processing device 130 may assign a smart tag to an object through the smart tag allocation unit 330 (step S430). A smart tag can be created by receiving a tag name for a designated object and setting search conditions for the designated object.

The object processing device 130 can create a hierarchical path for the object by hierarchically assigning other smart tags that do not have a mutual inclusion relationship to the smart tag assigned to the object through the smart tag allocation unit 330. (Step S450).

The object processing device 130 may provide a hierarchical path for the object as a breadcrumb during the object processing process through the breadcrumb processing unit 350 (step S470).

Figure 5 is a diagram explaining a smart tag according to the present invention.

Referring to FIG. 5, the object processing device 130 can attach smart tags to various user-defined objects created as a business project progresses in the kanban board-based object processing process. At this time, the user-defined object may include a kanban card 510 defined on the kanban board, a work note 520, a work chat room 530, and a work object 540 defined on the kanban board or kanban card 510. there is.

More specifically, the entire project can be progressed step by step through the Kanban board, and there may be multiple work projects in the entire project. The kanban card 510 defined on the kanban board can be created in response to each work project, and the work notes 520 and work objects 540 created during the progress of the corresponding work project are uploaded to the kanban card 510. and can be managed. Additionally, a work chat room 530 may be created and registered in the Kanban card 510 for communication between work participants of the work project. The progress or status of a work project can be managed through work progress stages.

For example, when work instructions are uploaded to the kanban card by the work instructor (Plan, P), the work progress stage of the kanban card becomes 'in progress'. In addition, if the task processor processes the task in accordance with the task instructions and uploads the task processing content as a result (Do, D), the task progress stage of the corresponding Kanban card becomes 'Confirming'. At this time, work-related content input by the work instructor or work handler can be recorded as a work note and uploaded to the Kanban card, and the card status of each Kanban card can be changed. Additionally, work-related content dependent on the work note can be created as a work object, that is, a task, and managed in relation to the work note, and the update of the work object can lead to the update of the related work note and kanban card, respectively.

Additionally, for a task that is 'being confirmed', the task manager can check the task processing content (Check, C) and terminate the task. In this case, the work progress stage of the task may be ‘ended’. On the other hand, after the work instructor confirms the work processing content, he or she may request work supplementation for the work processing content. In this way, when a request for work supplementation or a work supplementation instruction is uploaded to the kanban card by the work instructor, the work progress stage of the corresponding kanban card becomes 'complementing', and the card status of the corresponding kanban card may also be changed.

When the task handler supplements the task processing content corresponding to the content of the task supplementation instruction (Act, A), and the task supplement content is uploaded to the Kanban card by the task processor, or the uploaded task supplement content is uploaded by the task instructor If confirmed, the work progress stage of the corresponding Kanban card can be set to 'complementation complete'. And each kanban card can be classified according to the work progress stage and arranged on the kanban board.

In Figure 5, a smart tag can be defined including a tag name and search condition (condition). The object processing device 130 may provide an automatic attachment function to automatically attach tags to objects that meet the search conditions by setting search conditions while creating a smart tag.

Accordingly, the burden of having to attach smart tags one by one can be reduced, and smart tags can be easily attached and detached simply by changing the search conditions. Of course, it is also possible to manually attach smart tags one by one, so the user can directly attach smart tags to the kanban card 510 that does not meet the search conditions. Likewise, smart tags for individual kanban cards 510 may be manually deleted after assigning search conditions.

Additionally, the object processing device 130 can provide a call function for a smart tag, and the user can call the smart tag 530 using the tag name or call the smart tag using both the tag name and search conditions. You can. In one embodiment, access rights for calling may be set in the smart tag. Accordingly, only users who have been granted access rights can perform search and inquiry functions using smart tags in a limited manner.

Meanwhile, a smart tag can be attached to each kanban card 510 managed on the kanban board. In addition, smart tags can also be attached to work notes 520, work chat rooms 530, and work objects 540 managed on the kanban card 510. Accordingly, a complex search may be possible not only for the Kanban card 510 but also for other tabs on the Kanban board. For example, if you create a smart tag #a in the work notes tab (D tab in Figure 6) that shows work notes connected to work chat rooms that satisfy condition a, and then attach the smart tag to another work note, When you call the #a tag from the work notes tab, work notes using #a as a smart tag as well as work notes connected to work chat rooms searched with condition a can be searched.

Additionally, other smart tags can be added to smart tags as search conditions. For example, in the work chat room tab (C tab in Figure 6), the smart tag #abc is created and used to search for work chat rooms, and in the work note tab, #xyz is used to search for work notes connected to work chat rooms that satisfy the #abc condition. can be created as a smart tag. In other words, various types of combinations may be possible, as follows. ①tag of plan = tag of plan + search condition of plan, ②tag of check = tag of plan + check search condition, ③tag of plan = check tag + check search condition + act search condition.

Additionally, a smart tag may include a dashboard screen. The dashboard screen can display statistical values for search results using smart tags. For example, if there are multiple tabs like PDCA, when you call PLAN with a smart tag, statistical values for DO, CHECK, and ACT associated with it can also be displayed. Access to the dashboard screen may be granted on a limited basis.

Figures 6 and 7 are diagrams illustrating an embodiment of the attachment and search process for a smart tag according to the present invention.

Referring to FIG. 6, a smart tag may include the function of a general tag attached to each object, and may be automatically attached to an object that meets the search conditions by applying search conditions. In FIG. 6, tabs P (610), D, C, and A may exist on the kanban board 600. In the kanban card (P) area 610, a smart tag called ‘quality’ can be created. At this time, an interface 630 for creating a smart tag may be provided in the kanban card (P) area 610. If you set note (D) content = 'Quality' on the settings screen of the smart tag, a smart card is attached to the three kanban cards (@1, @2, @3) (510) connected to the work note containing the content of quality. Tags (#quality) can be automatically attached. Additionally, smart tags can be individually attached to separate kanban cards (@4) like regular tags.

Referring to FIG. 7, the object processing device 130 may provide a call (or search) for a smart tag. That is, the user can search for a smart tag with the tag name 'quality' through a separate search interface 650. Accordingly, a total of four kanban cards (@1, @2, @3, @4) 510a can be displayed as call results (or search results).

Figures 8 and 9 are diagrams illustrating an embodiment of a process for providing search results of a smart tag according to the present invention.

In FIG. 8, the object processing device 130 may search for an object using a smart tag attached to the object. The object processing device 130 may perform a search along a hierarchical path for objects associated with smart tags. The object processing device 130 can provide a call function for a smart tag to the user terminal 110, and the user can call the smart tag using the tag name or call the smart tag using both the tag name and search conditions. You can. When a smart tag is called, the object processing device 130 may provide the user terminal 110 with a search result related to the called smart tag. If the smart tag has a hierarchical tree structure including other smart tags, the structure of the selected smart tag may be displayed as a breadcrumb 810 in the upper right corner of the search result screen. When one smart tag is included in multiple smart tags and has two or more tree structures, two or more breadcrumbs 810 may be displayed. That is, when there are two or more breadcrumbs 810, all two or more breadcrumbs 810 can be displayed on the user terminal 110. Each time the user selects one of two or more breadcrumbs 810, the corresponding tree structure 830 may be replaced (updated) and displayed on the left side of the search results screen. For example, if the organization chart is implemented as a smart tag and the user belongs to two organizations, two breadcrumbs such as 'Sales/USA/Daejun Park' and 'Future/Daejun Park' can be displayed at the same time. On the left side of the search results screen, the selected smart tags are displayed in a tree structure 830 to visualize the entire smart tag structure. A plurality of objects 850 that satisfy the search conditions of the selected smart tag may be displayed at the bottom right of the search result screen. Here, the plurality of objects 850 may include search results regarding other smart tags included in the selected smart tag.

Referring to FIG. 9 , the object processing device 130 may display a statistical value 870 for a search result using a smart tag. For example, when you call a PLAN with a smart tag, statistical values for DO, CHECK, and ACT connected to it can also be displayed.

The object processing device 130 according to the present invention can provide a smart tag that provides an automatic attachment function on the PDCA structure. By specifying a tag name and search conditions on the smart tag, tags can be attached in batches and various searches can be performed using this. Results can be provided. In addition, the object processing device 130 hierarchically assigns smart tags to objects to create a hierarchical path for the object and displays the hierarchical path as a breadcrumb during the object processing process to access the object. By providing an accessible access path, work management efficiency can be improved.

Although the present invention has been described above with reference to preferred embodiments, those skilled in the art may make various modifications and changes to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You will understand that you can do it.

100: Object processing system
110: User terminal 130: Object processing device
310: Object creation unit 330: Smart tag allocation unit
350: Breadcrumb processing unit 370: Control unit
510: Kanban card 520: Work note
530: Work chat room 540: Work object
600: Kanban board 610: Kanban card area
630: Interface 650: Search Interface

Claims (18)

An object creation unit that creates an object;
A smart tag allocation unit that hierarchically assigns smart tags to the object to create a hierarchical path for the object, and the smart tag is created by receiving a tag name for the designated object and setting search conditions for the designated object. ; and
A hierarchical smart tag-based object processing device including a breadcrumb processing unit that provides the hierarchical path as a breadcrumb in the object processing process.
The method of claim 1, wherein the object creation unit
A hierarchical smart tag-based object processing device characterized in that the object is created as a work unit.
The method of claim 2, wherein the object creation unit
As the work unit, a hierarchical smart tag-based object processing device characterized in that it creates a work project, work note, work object, work chat room, kanban card, or kanban board.
The method of claim 1, wherein the smart tag allocation unit
A hierarchical smart tag-based object processing device, characterized in that the search conditions are composed of search keywords and search operators.
The method of claim 4, wherein the smart tag allocation unit
An object processing device based on a hierarchical smart tag, characterized in that the smart tag includes other smart tags that do not have a mutual inclusion relationship and hierarchically assigns a second smart tag to the first smart tag.
The method of claim 4, wherein the smart tag allocation unit
A hierarchical smart tag-based object processing device that sets user access rights to the smart tag and hides objects associated with the smart tag from users without access rights.
The method of claim 4, wherein the smart tag allocation unit
A hierarchical smart tag-based object processing device, characterized in that when a search through the smart tag is performed, a change in the corresponding object is detected and the change is notified through the breadcrumb.
The method of claim 1, wherein the breadcrumb processing unit
A hierarchical smart tag-based object processing device characterized in that when there are multiple hierarchical paths to the object, each is provided as an independent and separate breadcrumb.
The method of claim 8, wherein the breadcrumb processing unit
A hierarchical smart tag-based object processing device, characterized in that when one of the independent and separate breadcrumbs is selected, all smart tags associated with the smart tag in the selected breadcrumb are provided as a tree structure.
The method of claim 1, wherein the breadcrumb processing unit
A hierarchical smart tag-based object processing device that allows changing tag names or search conditions for smart tags in the breadcrumb.
The method of claim 1, wherein the breadcrumb processing unit
A hierarchical smart tag-based object processing device, characterized in that it provides object status for all objects associated with smart tags in the breadcrumb.
An object creation unit that creates an object;
a smart tag allocation unit that assigns a first smart tag to the object;
a hierarchical path generator that creates a hierarchical path for the object by hierarchically assigning a second smart tag to the first smart tag; and
A breadcrumb processing unit that provides the hierarchical path as a breadcrumb in the object processing process,
The first and second smart tags are a hierarchical smart tag-based object processing device that is created by receiving a tag name for a designated object and setting search conditions for the designated object.
An object creation step of creating an object;
A smart tag allocation step in which smart tags are hierarchically assigned to the object to create a hierarchical path for the object, and the smart tag is created by receiving a tag name for the designated object and setting search conditions for the designated object. ; and
A hierarchical smart tag-based object processing method including a breadcrumb processing step of providing the hierarchical path as a breadcrumb in the object processing process.
The method of claim 13, wherein the smart tag allocation step is
A hierarchical smart tag-based object processing method comprising the step of configuring the search conditions with search keywords and search operators.
The method of claim 14, wherein the smart tag allocation step is
A hierarchical smart tag-based object processing method comprising the step of hierarchically assigning a second smart tag to a first smart tag by including other smart tags with which a mutual inclusion relationship is not established in the smart tag.
The method of claim 14, wherein the smart tag allocation step is
A hierarchical smart tag-based object processing method comprising setting a user's access rights to the smart tag and hiding objects associated with the smart tag from users without access rights.
The method of claim 14, wherein the smart tag allocation step is
A hierarchical smart tag-based object processing method comprising detecting a change in the corresponding object when a search using the smart tag is performed and notifying the change through the breadcrumb.
The method of claim 13, wherein the breadcrumb processing step is
When there are multiple hierarchical paths to the object, providing each as an independent and separate breadcrumb. A hierarchical smart tag-based object processing method.