JP7274769B2 - Spatial design coordinating system, spatial design coordinating method and program - Google Patents

Description

The present invention relates to spatial design, and more particularly to techniques for coordinating spatial design.

A strategy for achieving corporate goals by converting the previous perception of exhibitions, which used to be an attempt to meet customers through viewing exhibits, demonstrations, and events, into an important marketing tool called exhibition marketing. In many cases, exhibitions are used as one of the effective means. Its scope is expanding to a comprehensive exhibition and convention business that combines additional events such as exhibitions and conferences, rather than a single industrial exhibition. It is the actual situation.

An exhibition booth is a basic space set up in advance in an exhibition hall. Exhibition booths can be variously classified according to materials and construction methods. For example, a system booth means an assembly system in which the basic framework, walls, lighting, etc. are commercialized. The materials are diverse, such as iron and aluminum, and the wall materials are also diverse, such as reinforced plastic and wood. However, it may be difficult to store and maintain the material because it is unnatural to express the exhibition booth.

Woodworking booths can be designed in a variety of ways, and although they are used in relatively large exhibitions, they are difficult to recycle. The mixed booth is a type of booth that combines the strengths of the iron material system, which can be recycled and assembled relatively easily, and the wooden booth, which allows free expression, and is often used in overseas exhibitions.

Small and medium-sized enterprises participating in exhibitions lack design competence compared to large enterprises. solved.

When a company participating in an exhibition asks for a booth design, a booth construction specialist requests a design from a professional designer and provides a booth design that meets the needs of the requesting company. Until now, client companies have only communicated information about booth design to designers in text or only abstract concepts, so there is a problem that designers cannot accurately grasp the requirements of client companies.

In addition, outsourcing of corporate exhibition booths is provided by a single freelancer designer or a single construction contractor. When commissioning a single freelancer designer or design contractor, the cost is high for small and medium-sized enterprises, and the cost is a burden for a single freelancer designer or contractor. Poor design performance.

The problem to be achieved by the present invention is to solve the problems of the prior art described above. By providing a space design coordinating system, method, and program that can provide services with design and construction costs, and provide one-stop services from exhibition preparation to exhibition management and booth removal. be.

According to an embodiment of the present invention, a design recommender for providing one or more recommended designs for spatial design in response to input from a client; providing an interface for customizing the recommended designs; and a customizing unit that generates a customized requested design based on the requester's inputs; and a cost estimate for realizing the requested design in an actual space received from a plurality of experts and sent to the requester. A spatial design coordinating system may be provided that includes an expert matching unit that provides the cost estimate and assists in matching between an expert selected by the client and the client.

In one embodiment, the design recommender includes a collection module that collects raw data images from one or more design sources; extracts spatial design components from each of the plurality of raw data images; and categorizes the extracted spatial design components into a classification module that classifies differently; a learning module that classifies and learns the plurality of raw data images by category to learn the arrangement of the spatial design components; and selects a plurality of design components corresponding to input from the requestor; A generation module may be included that generates one or more recommended designs that place the selected design components in the target space.

In one embodiment, the design components include one or more of walls, floors, ceilings, fixtures, exhibits, and decorations, and the categories may be classified by exhibit type or design concept.

In one embodiment, the classification module of the design recommender performs edge detection on the raw data images to obtain contours of the spatial design components, and includes contours in each raw data image based on the obtained contours. The spatial design components may be extracted from the extracted spatial design components, and the spatial design components may be classified and labeled based on the morphology of the extracted spatial design components.

In one embodiment, the customizing unit provides a graphical 3D stereoscopic view corresponding to the recommended design, and inputs change data for spatial design components displayed in the 3D stereoscopic view through the interface. A commissioned design can be generated based on the modified data.

In one embodiment, the customizing unit includes: a component providing module that provides information on one or more spatial design components that can be placed in a space; a spatial information storage module that stores information on a target space to be spatially designed; ;Providing the requester with information about one or more spatial design components provided by the component providing module, changing the information of the spatial design components included in the recommended design, or not included in the recommended design; a component modification module for adding spatial design components; a component placement module for modifying the placement of said spatial design components on the spatial design; and generating a commissioned design based on the added or changed components and the changed placement. can include a custom design generation module that

In one embodiment, the customizing unit may provide an interface based on the unreal 3D engine to the expert and an interface based on the html5 3D engine to the client.

In one embodiment, the expert matching unit includes a request transmission module for transmitting a 3D stereoscopic view of the requested design or request information for support services to a plurality of experts; A quote receiving module for receiving a cost estimate required for each construction part when applied to a space; and transmitting the cost estimate to the client, and conducting transactions between the client and an expert selected from the client. can include a transaction support module that supports

In one embodiment, the space design coordinating system provides a checklist and schedule information necessary for implementing the space design in an actual space, and recommends related service providers based on the checklist and schedule information. It can further include a coordinating unit that provides information.

In one embodiment, the space design coordinating system captures the actual space in which the requested design is implemented after the requested design is implemented in the actual space, stores the VR data as VR data, and stores the VR data. , the VR exhibition providing unit provides a VR meeting function between the client and the VR exhibition visitor, and the client provides the VR meeting function can be used to simulate the motion of the article to be advertised to the VR exhibition visitor in the VR space.

According to another embodiment of the present invention, a design recommendation step of providing one or more recommended designs for spatial design in response to input from a client; providing an interface for customizing the recommended designs; a customizing stage of generating a customized commissioned design based on a recommended design and inputs of said client; and receiving cost estimates from a plurality of experts for implementing said commissioned design in an actual space, said commissioning. A spatial design coordinating method may be provided that includes an expert matching stage that provides the cost estimate to a client and assists in matching between an expert selected by the client and the client.

According to another embodiment of the present invention, there may be provided a program stored in a computer-readable recording medium for causing a computer to perform the spatial design coordinating method.

According to an embodiment of the present invention, a design recommendation unit that provides one or more recommended designs for spatial design in response to input from a client and supports matching between a client and an expert selected by the client. By including an expert matching department, clients who have no exhibition experience can conveniently prepare for exhibitions, and services can be provided at reasonable design and construction costs. , exhibition management, and booth removal.

1 is a block diagram illustrating the configuration of a spatial design coordinating system according to one embodiment of the present invention; FIG. 1 is a block diagram showing the configuration of a design recommendation section of a spatial design coordinating system according to an embodiment of the present invention; FIG. 1 is a block diagram showing the configuration of a customizing section of a spatial design coordinating system according to one embodiment of the present invention; FIG. 2 is a block diagram showing the configuration of an expert matching unit of the spatial design coordinating system according to one embodiment of the present invention; FIG. 4 is a flowchart of a spatial design coordinating method performed by a spatial design coordinating system according to an embodiment of the present invention;

Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

The terms used in the present invention were selected as general terms that are currently widely used as much as possible while considering the functions of the present invention, but this is not the intent of engineers engaged in the field, precedents, or the emergence of new technologies. etc., can change. There are also terms arbitrarily chosen by the applicant in certain cases, in which case the meaning will be set forth in detail in the relevant description of the invention. Therefore, the terms used in the present invention should be defined based on the meanings of the terms and the overall content of the present invention rather than just the names of the terms.

Throughout the specification, when a part "includes" any component, this does not exclude other components unless specifically stated to the contrary, and means that it may further include other components. . In addition, terms such as `` ... unit '' and `` module '' described in the specification mean a unit that processes at least one or more functions or operations, which may be implemented by hardware or software, or by hardware and software. can be embodied by a combination of

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily implement the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In addition, in order to clearly explain the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

FIG. 1 is a block diagram illustrating the configuration of a spatial design coordinating system 1 according to one embodiment of the present invention.

Referring to FIG. 1, a spatial design coordinating system 1 can be connected with a client 2, a designer 3, a contractor 4 and a supporter 5 through a network. The spatial design coordinating system 1 can include an input receiving unit 10, a database 20, a design recommending unit 30, a customizing unit 40, an expert matching unit 50, a coordinating unit 60, and a VR exhibition providing unit .

Spatial design coordinating system 1 is embodied in a web server and application (or homepage), and through online (internet, ARS, telephone consultation service), a client who desires spatial design construction and an expert (designer) who can provide spatial design. Intermediary service between professionals (construction contractors and support contractors) who can provide interior construction services and the like.

The web server has the same configuration as a general web server in terms of hardware, and is implemented in various languages such as C, C++, Java, Visual Basic, Visual C, etc. in terms of software. , can include program modules that perform various functions. In addition, various web server programs are provided according to the operating system such as DOS, Windows, Linux, Unix, Macintosh, etc. for general server hardware. can be embodied using

In addition, the web server is connected to a client communication terminal, a designer communication terminal, a construction company communication terminal, and a support company communication terminal through a network. LTE (Long Term Evolution) network, 5GPP (5th Generation Partnership Project) network, WIMAX (World Interoperability for Microwave Access) network, Internet, LAN (Local Area Network), W Wireless LAN (Wireless Local Area Network), WAN ( Wide Area Network), PAN (Personal Area Network), Bluetooth network, NFC network, satellite broadcasting network, analog broadcasting network, DMB (Digital Multimedia Broadcasting) network, etc., but not limited thereto.

The client communication terminal, the designer communication terminal, the contractor communication terminal, and the cooperator communication terminal are PCS (Personal Communication System), GSM (Global System for Mobile Communications), PDC (Personal Digital Cellular), PHS (Personal Handyphone). System) , PDA (Personal Digital Assistant), IMT (International Mobile Telecommunications)-2000, CDMA (Code Division Multiple Access)-2000, W-CDMA (W-Code Multiple A access), Wibro (Wireless Broadband Internet) terminal, smartphone ), smart pads, tablet PCs, etc., as well as general PCs.

Hereinafter, for convenience of explanation, the communication terminal of the client will be called the client, the communication terminal of the designer will be called the designer, the communication terminal of the construction company will be called the construction company, and the communication terminal of the support company will be called the support company.

The input reception unit 10 of the space design coordinating system 1 can receive inputs from the client 2, the designer 3, the construction company 4, and the support company 5.

Client 2 provides required information such as category, type of business, size, budget, design concept, etc. for the spatial design to be constructed, and other services necessary for holding exhibitions or expositions such as printing, guidance, interpretation, and customs clearance. Request information can be entered into the spatial design coordinating system 1 .

When the designer 3 receives from the space design coordinating system 1 a request for a cost estimate for the requested design confirmed by the client 2, the designer 3 prepares a cost estimate for creating detailed design data necessary to embody the requested design in an actual space. Then, the cost estimate data can be input to the spatial design coordinating system 1 through the input reception unit 10. FIG.

The contractor 4 can construct the space design into an actual exhibition booth or an actual apartment space. When the contractor 4 receives a request from the space design coordinating system 1 regarding the cost estimate required when constructing the requested design confirmed by the client 2 in an actual space, the contractor 4 prepares the cost estimate required for construction. Then, the cost estimate data can be input to the space design coordinating system 1 through the input reception unit 10. FIG.

The supporter 5 can provide services other than the construction necessary for holding an exhibition or exposition, such as printing of pamphlets, guidance, interpretation, and customs clearance. When the support provider 5 receives a cost estimate request for the support service determined by the client 2 from the space design coordinating system 1, the support company 5 creates a cost estimate required for the support service and inputs the cost estimate data to the reception unit. 10 can be input to the spatial design coordinating system 1.

The design recommendation unit 30 of the spatial design coordinating system 1 can provide one or more recommended designs regarding spatial design in response to the input from the client 2 . The client 2 can select one requested design from one or more recommended designs recommended by the design recommendation unit 30 . In one embodiment, the design recommendation unit 30 may generate three recommended designs and transmit the generated three recommended designs to the client 2 . In another embodiment, the design recommendation unit 30 may generate 2, 4, 6, etc. recommended designs and transmit them to the client 2 . The number of recommended designs provided by the design recommendation unit 30 is not limited to this embodiment, and providing one or more recommended designs is included within the scope of the technical concept of the present invention.

The design recommendation unit 30 can generate one or more recommended designs from pre-stored raw data images by a classification and learning algorithm using artificial intelligence (AI). Raw data images can be collected from public data available on the Internet, design platforms, design libraries, or design magazines such as books.

The design recommendation unit 30 can extract spatial design components that form a spatial design from the collected raw data images. For example, the spatial design component means the walls, bottom, ceiling, installations, exhibits, decorations, etc. that make up the spatial design, and the spatial design component is the wall, bottom, ceiling, installations, etc. from the collected raw data image. Information such as the shape, size, color, and material of exhibits and decorations can be obtained.

The design recommendation unit 30 classifies and learns the extracted spatial design components by category, and can learn the arrangement of the spatial design components. In addition, the design recommendation unit 30 can generate a recommended design in which a plurality of design components are arranged in the target space in response to a detailed request for the space design input by the client. A specific process of generating a recommended design by the design recommendation unit 30 will be described later.

The customizing unit 40 of the spatial design coordinating system 1 can provide an interface for customizing the recommended design. The customizing unit 40 can generate a customized commissioned design based on the recommended design and modifications or additional inputs to the spatial design components from the client 2 .

The client 2 can select one design from several recommended designs recommended by the design recommendation section 30 . The client 2 can create a requested design by changing the details of the recommended design through the customizing section 4 of the spatial design coordinating system 1 . A specific customizing process performed by the customizing section 4 will be described later.

The expert matching unit 50 of the spatial design coordinating system 1 can receive cost estimates from a plurality of experts for realizing the requested design in the actual space and provide the client 2 with the cost estimates. The expert matching unit 50 can support matching between the experts 3 , 4 and 5 selected by the client 2 and the client 2 .

The client 2 can select a designer 3, a contractor 4, and a supporter 5 in order to implement the selected requested design in an actual space. The expert matching unit 50 can transmit information on the selected requested design to the designer 3, the construction company 4, and the support company 5, respectively. The designer 3, the contractor 4, and the supporter 5 can create a cost estimate for the selected requested design and transmit it to the spatial design coordinating system 1 through the expert matching unit 50. FIG.

After receiving the cost estimates from experts 3, 4, and 5, the expert matching unit 50 can transmit the cost estimates to the client 2. FIG. After reviewing the received cost estimate, the client 2 can select one of the plurality of designers 3, builders 4, and supporters 5 who provided the cost estimates to proceed with the contract. After the client 2 selects an expert, the expert matching unit 50 can support services such as contract conclusion and payment settlement between the client 2 and the designer 3, the construction company 4, and the support company 5. .

The coordinating unit 60 of the spatial design coordinating system 1 provides a checklist and schedule information necessary for implementing the spatial design in an actual space, and is prepared to meet the schedule based on the checklist and schedule information. It can notify the client 2 about unsatisfactory matters, and recommend other specialists (interpretation, customs clearance, printing, guidance, broadcasting, video recording, photography, etc.) as necessary.

In one embodiment, the spatial design coordinating system 1 periodically transmits a checklist for exhibit management to the client 2, and the client 2 can fill in the completed items in the received checklist. . For items on the checklist marked as incomplete, a cost estimate will be obtained from a specialist in the relevant service (interpretation, customs clearance, printing, guidance, broadcasting, video recording, photography, etc.), and will be automatically sent to Client 2. can be transmitted.

After the requested design is realized in the actual space, the VR exhibition providing unit 70 of the space design coordinating system 1 captures the actual space in which the requested design is realized, saves it as VR data, and saves the saved VR data. It can be used to provide online VR exhibition services.

If the exhibition or exposition is held after the booth design is completed and the actual construction is completed, the exhibition booth must be removed when the exhibition or exposition schedule ends. The VR exhibition providing unit 70 can store and provide the actual space in which the requested design such as the booth design is implemented as VR data.

Even after the exhibition ends, the general public can access the space design coordinating system 1 and visit the exhibition booth after the schedule provided by the VR exhibition providing unit 70 through the VR image. Along with this, the client 2 can use the virtual space to publicize their own services or products even after the exhibition or expo ends.

The VR exhibition providing unit 70 can provide a VR meeting function between the client 2 and VR exhibition visitors. The client 2 can use the VR meeting function to simulate the movement of the promotional item to VR exhibition visitors in the VR space.

Client 2 and VR exhibit visitors can wear VR headsets to take advantage of the VR meeting functionality. When the VR exhibition visitor connects to the VR exhibition hall of the space design coordinating system 1, the client 2 may be sent a message or mail to the effect that there is a VR exhibition visitor.

After wearing a VR headset and preparing a VR controller, the client 2 can connect to the space design coordinating system 1 to advertise specific items to VR exhibition visitors. The client 2 can use the VR controller to show the motion of the publicity target article to the VR exhibition visitors in the VR space.

The VR exhibition providing unit 70 can generate in advance a VR object that is a 3D model of the promotional product using the image data of the promotional product. 3D modeling generates a form inflection point and a form line object of a promotion target article based on image data of the promotion target article, and uses the generated form inflection point and form line object to create a polygon data type 3D model. This can be accomplished by generating Creation of a VR object can be accomplished by mapping materials to fit a polygonal object and rendering the change in hue, texture, and specific manipulation of the object.

Client 2 uses the VR headset and VR controller worn by client 2 to explain the features of the promotion target item and the differences from existing products, etc., and manipulate the promotion target product in the VR space to control the motion of the target target product. can be simulated. For example, client 2 can simulate the functions of a newly released smartphone in the VR space. Also, the client 2 can simulate the rotational motion of the new type motor in the VR space.

A VR exhibition visitor can use the VR headset worn to converse with the client 2 and directly inquire about the item. Along with this, the client 2 can explain or carry out marketing activities on the publicity object at any time in the virtual space with VR exhibition visitors located at a remote location.

The database 20 of the spatial design coordinating system 1 contains information on the client 2 (login information, contact information, design request information, etc.), information on the designer 3 (login information, contact information, estimate information, etc.), and the contractor 4. information (login information, contact information, estimate information, etc.) and information related to the support provider 5 (login information, contact information, estimate information, etc.) can be saved.

The database 20 can store raw data images collected by the design recommendation unit 30 from public data, design platforms, design libraries, books, etc., information on spatial design components extracted by the design recommendation unit 30, and recommended design information for each category. can. In addition, the database 20 can store checklist information and schedule information used by the coordinating section 60 and VR data of exhibition booths used by the VR exhibition providing section 70 .

FIG. 2 is a block diagram showing the configuration of the design recommendation section 30 of the spatial design coordinating system 1 according to one embodiment of the present invention.

Referring to FIG. 2 , the design recommender 30 can include a collection module 31 , a classification module 32 , a learning module 33 , a recommended design generation module 34 and a recommendation exclusion module 35 .

The collection module 31 can collect raw data images from one or more design sources. Raw data images can be collected from public data available on the Internet, design platforms, design libraries, or design magazines such as books.

Classification module 32 may extract spatial design components from each of the plurality of raw data images and classify the extracted spatial design components into categories. For example, spatial design components can include walls, floors, ceilings, fixtures, exhibits, decorations, etc. that make up the spatial design. The classification module 32 can extract spatial design components such as walls, floors, ceilings, installations, exhibits, decorations, etc. from raw data images and classify the extracted components into categories.

The categories sorted by the sorting module 32 can include exhibition lines or design concepts. The exhibition industries can include various industries such as baby goods, children's goods, student goods, semiconductor industry, printing industry, leisure industry, machinery industry, 3D printing industry and so on. The design concept can include modern style, northern European style, natural style, vintage style, classic antique style, oriental style and unique style, etc.

The modern style uses materials such as iron, glass, and leather, and mainly uses achromatic colors such as white and black, as well as vivid hues. The Northern European style uses materials such as natural wood, tiles, and stainless steel, and white, beige, and pastel tones are the main colors used, giving it a smooth finish.

The natural style uses natural materials such as wood and linen fabric, and mainly uses brown, cream, and natural colors to create a casual and comfortable style. The vintage style uses materials such as bricks, iron, glass, and plastic, and uses dark brown, gray, and black hues predominantly, giving it a rough and unprepared look.

The classic antique style uses materials such as wood, leather, woolen fabric, and silk fabric, and mainly uses brown, black, and subdued colors, giving a sense of antiquity and elegance. The oriental style uses materials such as wood, earth, and rattan, and uses mainly brown and natural hues, and has a rough finish. The unique style is a style that uses various new materials and mainly uses primary colors or vivid colors to give a lively feeling.

The classification module 32 performs edge detection on the raw data images to obtain the contours of the spatial design components, extracts the spatial design components contained in each raw data image based on the obtained contours, and classifies the extracted spatial design components. Spatial design components can be classified and labeled based on the morphology of the design components.

In one embodiment, the classification module 32 obtains the contours of walls, ceilings, floors, fixtures, etc. contained in the raw data image, and classifies the spaces of the walls, ceiling, floor, fixtures, etc. based on the obtained contours. Design components can be extracted. In addition, the classification module 32 may classify and label the corresponding spatial design components as walls, ceilings, floors, installations, etc. based on the shape of the extracted spatial design components.

The learning module 33 can categorize and learn multiple raw data images to learn placement of spatial design components. In one embodiment, learning module 33 classifies raw data images collected from public data, design platforms, design libraries, books, etc. into detailed categories, such as baby products, kids products, semiconductor industry, defense industry, cosmetics, entrepreneurship, etc. It can be classified and learned separately to learn the proper arrangement of the installations (chairs, tables, coffee machines, advertising signs, etc.) of the extracted spatial design components.

The recommended design generation module 34 can select a plurality of design components corresponding to the input from the client and generate one or more recommended designs by arranging the selected plurality of design components in the target space.

In one embodiment, when the requester inputs the concept of natural style as a detailed request, the recommendation design generating module 34 generates the design components (display components) of the exhibition booth related to outdoor products and natural style. booth floor, walls, chairs, tables, billboards, outdoor fixtures and supplies) and generate three recommended designs that place the selected design components into the exhibition booth.

When the recommended design generation module 34 generates a recommended design, the configuration and arrangement information of design components learned by the learning module 33 using a plurality of raw data images may be reflected. In addition, the recommended design generation module 34 can also determine recommended designs for each category based on scores evaluated by an expert such as the client 2 or the designer 3 in an existing requested case.

The recommendation exclusion module 35 compares the recommended design with any one of a plurality of raw data images to calculate the degree of similarity, and if the calculated degree of similarity is greater than or equal to a specified value, the recommended design is sent to the requester 2. can be excluded from providing to If the similarity is equal to or greater than a specified value, for example, 80%, the recommended design may infringe on the copyright or design right associated with the raw data image, so the design may be excluded from the recommended designs.

FIG. 3 is a block diagram showing the configuration of the customizing section 40 of the spatial design coordinating system 1 according to one embodiment of the present invention.

Referring to FIG. 3, the customizing unit 40 can include a component provision module 41, a spatial information storage module 42, a component change module 43, a component placement module 44 and a requested design generation module 45. FIG.

The component providing module 41 can provide information about one or more space design components that can be arranged in the space based on the information about the space design components extracted and classified by the design recommendation unit 30 . In one embodiment, the component providing module 41 can provide information (color, material, size, etc.) about spatial design components such as exhibition booth floors, walls, chairs, tables, billboards, and outdoor products.

The spatial information storage module 42 can store information about a target space for spatial design. In one embodiment, the spatial information storage module 42 may store information about the size (width, length, height, etc.) of the exhibition booth input by the client 2 .

The component change module 43 provides the requester 3 with information about one or more spatial design components provided by the component providing module, changes the information on the spatial design components included in the recommended design, or changes the information on the spatial design components included in the recommended design. Spatial design components can be added that are not

In one embodiment, when the client 3 wants to change the floor material of the exhibition booth, the table, the billboard, etc. included in the component recommendation design, the components are provided by the component provision module 41 using the change module 43 . Other base materials, tables, billboards, etc. can be used to change the recommended design.

In addition, when the client 3 wishes to add ceiling lighting not included in the recommended design, the client 3 uses the change module 43 to select desired lighting from various ceiling lighting provided by the component providing module 41. Can be selected and added within the recommended design.

The component placement module 44 can change the placement of spatial design components on the spatial design. If the client 2 does not like the arrangement of the spatial design components arranged in the recommended design, the client 2 can move the corresponding spatial design components through the component arrangement module 44 by drag-and-drag operations.

The commissioned design generation module 45 can generate the commissioned design based on the added or modified components and the modified placement. The commissioned design generation module 45 can generate commissioned designs in two or more data formats that can be used by two or more 3D graphics engines of different schemes. In one embodiment, the two or more data formats can include data formats usable with the html5 3D engine or the unreal 3D engine.

The html5 3D engine has a fast processing speed when running on the web, but it is difficult to express details such as component materials. The unreal 3D engine has a slower processing speed than the html5 3D engine when running on the web, but is capable of more detailed expressions such as component materials than the html5 3D engine.

Since the client 2 connects to the spatial design coordinating system 1 through a web or mobile application, the interface provided by the customizing unit 40 requires fast processing speed. Designer 3, however, cares more about design details than processing speed. Since it is difficult for the designer 3 to design the exhibition booth in detail depending on the html5 3D engine, the designer 3 can be provided with an interface based on the Unreal 3D engine that enables more realistic and detailed design. In this regard, the commissioned design generation module 45 can be configured to generate designs in two data formats usable with the html5 3D engine and the unreal 3D engine.

FIG. 4 is a block diagram showing the configuration of the expert matching section 50 of the spatial design coordinating system 1 according to one embodiment of the present invention.

Referring to FIG. 4 , the expert matching unit 50 can include a request transmission module 51 , a quote reception module 52 and a transaction support module 53 .

The request transmission module 51 can transmit a 3D stereoscopic drawing of a requested design selected by the client 2 or request information for a support service used in operating an exhibition to a plurality of experts. The client 2 changes the recommended design to suit his/her own preference, confirms the requested design, and sends request information for other services (interpretation, guidance, pamphlet printing, etc.) necessary for the exhibition to the spatial information coordinating system 1. can be entered. The request transmission module 51 of the coordinating system 1 can transmit the confirmed 3D drawing of the requested design and the request information for the support service to the designer, the contractor, or the supporter.

The estimate receiving module 52 is used to estimate the cost of detailed design required when applying designs requested by multiple experts to an actual space, estimate the cost required for each construction part, or estimate the cost required for support services. can accept In one embodiment, the designer 3 transmits a cost estimate of 1 million won for the detailed design of the requested design, the contractor 4 transmits a cost estimate of 2 million won for the construction of the requested design, and the printing specialist A support company 5 such as can transmit a cost estimate of 500,000 won for printing pamphlets.

The transaction support module 53 can transmit cost estimates received from the experts to the client 2 to facilitate transactions between the selected expert and the client 2 . After reviewing the received cost estimate, the client 2 can select one of the plurality of designers 3, builders 4, and supporters 5 who provided the cost estimates to proceed with the contract. After the client 2 selects an expert, the expert matching unit 50 can support services such as contract conclusion and payment settlement between the client 2 and the designer 3, the construction company 4, and the support company 5. .

FIG. 5 is a flowchart illustrating the process of a spatial design coordinating method performed by the spatial design coordinating system 1 according to one embodiment of the present invention.

The spatial design coordinating system 1 can perform a design request receiving step (S10) for receiving requests for spatial design from the client 2. FIG. The client 2 can input request information such as the category, type of business, size, budget, and design concept for the spatial design that the client 2 wishes to construct into the spatial design coordinating system 1 . In addition, the client 2 can input other service request information necessary for holding an exhibition or exposition, such as printing, guidance, interpretation, and customs clearance, into the spatial design coordinating system 1 .

When a design request is received from the client 2, the space design coordinating system 1 performs a design recommendation step (S20) of providing one or more recommended designs for the space design in response to the input from the client 2. can be done. The client 2 can select one requested design from one or more recommended designs recommended by the design recommendation unit 30 . In one embodiment, the design recommendation unit 30 may generate three recommended designs and transmit the generated three recommended designs to the client 2 .

After the recommended design is transmitted, the spatial design coordinating system 1 provides an interface for customizing the recommended design, and customization is performed based on the recommended design and changes or additional inputs to the spatial design components from the client 2. A customizing step (S30) can be performed to generate a custom design. The client 2 can select one design from several recommended designs recommended by the design recommendation section 30 . The client 2 can create a requested design by changing details of the recommended design through an interface provided by the customizing section 4 of the spatial design coordinating system 1 .

When the requested design is generated, the space design coordinating system 1 receives cost estimates for implementing the requested design in an actual space or cost estimates for required support services from a plurality of experts and sends them to the client 2. An expert matching step (S40) may be performed to provide a cost estimate. After the client 2 selects a specialist, the spatial design coordinating system 1 can provide services such as contract conclusion and payment settlement between the client 2 and the designer 3, the construction company 4, and the support company 5.

When the contract between the client 2 and the expert is concluded, the spatial design coordinating system 1 performs a coordinating step (S50) of providing checklists and schedule information necessary for implementing the spatial design in the actual space. can be carried out. The spatial design coordinating system 1 notifies the client 2 of matters that have not been prepared to meet the schedule in the coordinating stage (S50), and if necessary, other specialists (interpreter, customs clearance, printing, guidance, broadcasting, video recording, filming) can be recommended.

The spatial design coordinating system 1 periodically transmits a checklist for exhibition management to the client 2, and the client 2 can fill in the completed items in the received checklist. For items on the checklist marked as incomplete, we will receive a cost estimate from a specialist in the relevant service (interpretation, customs clearance, printing, guidance, broadcasting, video recording, photography, etc.) and automatically send it to Client 2. can be transmitted in

When the actual exhibition booth is completed by the requested design, the space design coordinating system 1 captures the actual space in which the requested design is realized, saves it as VR data, and uses the saved VR data to perform online VR. A VR exhibition providing step (S60) of providing an exhibition service may be performed. Accordingly, even after the exhibition or exposition ends, the general public can connect to the space design coordinating system 1 and visit the exhibition booth after the schedule provided by the VR exhibition providing unit 70 through the VR image. , the client 2 can use the virtual space for advertising their services or products.

In the above, as an embodiment of the present invention, the target of spatial design is illustrated as an exhibition booth, but the target of spatial design in the present invention is not limited to an exhibition booth, and can be a performance hall, a drama set field, an event booth, or inside a house. Any space such as an interior or a shopping street interior is included in the object of the spatial design of the present invention.

The steps or processes described above may be performed by hardware components, software components, and/or a combination of hardware and software components. For example, the steps or processes described in the embodiments may include, for example, processors, controllers, arithmetic logic units (ALUs), digital signal processors (microcomputers), field programmable arrays (FPAs), programmable logic units (PLUs), ), microprocessors, or some other device capable of executing and responding to instructions, may be implemented using one or more general purpose or special purpose computers. A processing device is capable of running an operating system (OS) and one or more software applications running on the operating system. The processor may also access, store, manipulate, process and generate data in response to executing the software. For convenience of understanding, the processing unit may be described as one, but those skilled in the art will understand that the processing unit may include a plurality of processing elements and/or processing elements. Alternatively, it can be understood that multiple types of processing elements can be included. For example, a processing device may include multiple processors or a processor and a controller. Also, different processing configurations are possible, such as parallel processors.

The software may include computer programs, code, instructions, or a combination of one or more of these to configure or independently configure the processor to operate as desired. Or it can collectively command the processors. Software and/or data may be any type of machine, component, physical device, virtual equipment, to be interpreted by or to provide instructions or data to a processor. It may be embodied permanently or temporarily in a computer storage medium or device, or in a transmitted signal wave. The software may also be distributed over network coupled computer systems so that it is stored and executed in a distributed fashion. Software and data may be stored on one or more computer readable media.

The method according to the embodiments can be embodied in the form of program instructions that can be executed through various computer means and recorded on a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, etc. singly or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the embodiment, or they may be of the kind known and available to those skilled in the art. Examples of computer readable recording media include magnetic media such as hard disks, floppy disks and magnetic tapes; optical media such as CD-ROMs, DVDs; magneto-optical media such as disk) and hardware devices specially configured to store and execute program instructions such as ROM, RAM, flash memory, etc. is included. Examples of program instructions include machine language code, such as that produced by a compiler, as well as high-level language code that may be executed by a computer using an interpreter or the like. The hardware device may be configured to act as one or more software modules to perform the operations of embodiments, and vice versa.

Although the embodiments have been described with limited embodiments and drawings as described above, various modifications and variations can be made by those skilled in the art based on the above description. For example, the techniques described may be performed in a different order than in the manner described and/or components such as systems, structures, devices, circuits, etc. described may be combined or combined in a manner different than in the manner described. , may be substituted with other components or with equivalents and still achieve suitable results.

Therefore, other implementations, other embodiments, and equivalents of the claims are also within the scope of the following claims.

Claims (11)

a design recommender that provides one or more recommended designs for spatial design in response to input from a client;
a customizing component that provides an interface for customizing the recommended design and generates a customized commissioned design based on the recommended design and the requester's input; and
Receive cost estimates for realizing the requested design in an actual space from a plurality of experts, provide the cost estimates to the client, and match the experts selected by the client with the client. including an expert matching department that assists in
The design recommendation unit
a collection module that collects raw data images from one or more design sources;
a classification module for extracting spatial design components from each of the plurality of raw data images and classifying the extracted spatial design components into categories;
a learning module that classifies and learns the plurality of raw data images by category and learns the arrangement of the spatial design components; and selects a plurality of design components corresponding to input from the requester and selects a plurality of selected designs. A spatial design coordinating system that includes a generator module that generates one or more recommended designs with components arranged in a target space. the design components include one or more of walls, floors, ceilings, installations, exhibits and decorations;
2. The spatial design coordinating system of claim 1 , wherein the categories are classified by exhibition type or design concept. The classification module of the design recommender comprises:
performing edge detection on the raw data image to obtain contours of the spatial design component;
extracting the spatial design components contained in each raw data image based on the obtained contours;
2. The spatial design coordinating system of claim 1 , wherein the extracted spatial design components are classified and labeled based on the morphology of the spatial design components. The customizing unit
providing a graphical three-dimensional view corresponding to the recommended design;
2. The spatial design coordinating system according to claim 1, wherein change data for spatial design components displayed in said three-dimensional stereoscopic drawing is input through said interface, and a requested design is generated based on said change data. The customizing unit
a component-providing module that provides information about one or more spatial design components that can be placed in a space;
Spatial information storage module for storing information about the target space for spatial design;
Providing the requester with information on one or more spatial design components provided by the component providing module, changing the information on the spatial design components included in the recommended design, or providing a space not included in the recommended design. Component modification module for adding design components;
5. The method of claim 4 , comprising a component placement module for changing placement of said spatial design components on the spatial design; and a commissioned design generation module for generating a commissioned design based on the added or changed components and the changed placement. Described spatial design coordinating system. a design recommender that provides one or more recommended designs for spatial design in response to input from a client;
a customizing component that provides an interface for customizing the recommended design and generates a customized commissioned design based on the recommended design and the requester's input; and
Receive cost estimates for realizing the requested design in an actual space from a plurality of experts, provide the cost estimates to the client, and match the experts selected by the client with the client. including an expert matching department that assists in
A spatial design coordinating system, wherein the customizing unit provides an interface based on the unreal 3D engine for the expert and an interface based on the html5 3D engine for the client. The expert matching unit
a request transmission module for transmitting a 3D stereoscopic drawing of the requested design or request information for support services to a plurality of experts;
An estimate receiving module for receiving estimates of costs required for each construction part when applying the requested design to an actual space from the plurality of experts; 7. The spatial design coordinating system of claim 6 , including a transaction support module for assisting transactions between a selected expert and said client. a design recommender that provides one or more recommended designs for spatial design in response to input from a client;
a customizing unit that provides an interface for customizing the recommended design and generates a customized requested design based on the recommended design and the requester's input;
Receive cost estimates for realizing the requested design in an actual space from a plurality of experts, provide the cost estimates to the client, and match the experts selected by the client with the client. and a checklist and schedule information necessary for embodying the space design in an actual space, and providing information on recommendations for related service providers based on the checklist and schedule information. Spatial design coordinating system, including a coordinating department that a design recommender that provides one or more recommended designs for spatial design in response to input from a client;
a customizing unit that provides an interface for customizing the recommended design and generates a customized requested design based on the recommended design and the requester's input;
Receive cost estimates for realizing the requested design in an actual space from a plurality of experts, provide the cost estimates to the client, and match the experts selected by the client with the client. and after the requested design is realized in the actual space, the actual space in which the requested design is realized is photographed and saved as VR data, and the saved VR data is used. including a VR exhibition providing department that provides online VR exhibition services at
The VR exhibition providing unit provides a VR meeting function between the requester and the VR exhibition visitor,
A spatial design coordinating system in which the client uses the VR meeting function to simulate the movement of the promotional article for the VR exhibition visitor in the VR space. a design recommendation stage for providing one or more recommended designs for spatial design in response to input from a client;
a customizing stage of providing an interface for customizing the recommended design and generating a customized requested design based on the recommended design and the requester's input; and embodying the requested design in an actual space. an expert matching stage for receiving cost estimates from a plurality of experts and providing said cost estimates to said client to facilitate matching between said client and an expert selected by said client; including
The customizing step provides an interface based on the unreal 3D engine to the expert and an interface based on the html5 3D engine to the client . A program stored in a computer-readable recording medium for causing a computer to perform the spatial design coordinating method according to claim 10 .

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