CN107770233B - Decoration process control method and device - Google Patents

Abstract

The invention provides a decoration process control method and device, which are applied to a server, wherein the server can be accessed by a plurality of first user terminals. The decoration process control method comprises the following steps: receiving first request information sent by a first user terminal, and searching a modeling function corresponding to the first request information in a pre-stored modeling function library; receiving user type parameter information sent by a first user terminal; processing the house type parameter information through the modeling function, generating a house frame 3D model and sending the house frame 3D model to a first user terminal; receiving second request information sent by the first user terminal, and searching decoration effect information corresponding to the second request information in a pre-stored decoration effect database; and generating a decoration effect display model of the house frame 3D model according to the decoration effect information and sending the decoration effect display model to the first user terminal.

Description

Decoration process control method and device

Technical Field

The invention relates to the technical field of decoration, in particular to a decoration process control method and device.

Background

The current house decoration design is limited by the level of designers, and the finally designed decoration scheme cannot completely meet the requirements of users. Required fitment product kind is miscellaneous in the fitment process, and it is extremely inconvenient to purchase, needs to choose one by one and purchases, and the fitment product of choosing carefully can not reach the same effect with the plan view. In addition, in the existing decoration process, users, designers, construction parties, decoration product providers and the like are greatly inconvenient, and the effect deviation between the designed effect diagram and the finished effect of actual decoration is large due to the disjunction of the decoration scheme design in the early stage and the decoration construction in the later stage.

Disclosure of Invention

In view of this, embodiments of the present invention provide a method and an apparatus for managing and controlling a decoration process, which can solve the above problems.

In order to achieve the purpose, the embodiment of the invention adopts the following technical scheme:

a decoration process control method is applied to a server and comprises the following steps:

receiving first request information sent by a first user terminal, and searching a modeling function corresponding to the first request information in a pre-stored modeling function library;

receiving user type parameter information sent by a first user terminal;

processing the house type parameter information through the modeling function, generating a house frame 3D model and sending the house frame 3D model to a first user terminal;

receiving second request information sent by a first user terminal, and searching decoration effect information corresponding to the second request information in a pre-stored decoration effect database, wherein the decoration effect information comprises decoration budget, decoration style and house function or overall design effect;

generating a decoration effect display model about the 3D model of the house frame according to the decoration effect information; and

calculating and counting to obtain a decoration process, construction risk, a decoration period and a decoration budget list matched with the decoration effect information, and generating a decoration scheme description file comprising the decoration process, the construction risk, the decoration period and the decoration budget list;

and sending the decoration scheme description file and the decoration effect display model related to the house frame 3D model to the first user terminal.

The invention also provides a decoration process control device, which is applied to a server, wherein the server can be accessed by a plurality of first user terminals through a network, and the decoration process control device comprises a modeling mode selection module, a house parameter acquisition module, a 3D model generation module, a decoration effect selection module, a 3D effect graph generation module, a decoration scheme generation module and a sending module;

the modeling mode selection module is used for receiving first request information sent by a first user terminal and searching a modeling function corresponding to the first request information in a prestored modeling function library;

the house parameter acquisition module is used for receiving the user type parameter information sent by the first user terminal;

the 3D model generation module is used for processing the house type parameter information through the modeling function, generating a house frame 3D model and sending the house frame 3D model to the first user terminal;

the decoration effect selection module is used for receiving second request information sent by the first user terminal, and searching decoration effect information corresponding to the second request information in a prestored decoration effect database, wherein the decoration effect information comprises decoration budget, decoration style and house function or overall design effect;

the 3D effect graph generating module is used for generating a decoration effect display model of the house frame 3D model according to the decoration effect information;

the decoration scheme generation module is used for counting decoration processes, construction risks, decoration period and a decoration budget list matched with the decoration effect information and generating a decoration scheme description file comprising the decoration processes, the construction risks, the decoration period and the decoration budget list;

the sending module is used for sending the decoration scheme description file and the decoration effect display model related to the house frame 3D model to the first user terminal.

The decoration process control method and the device provided by the embodiment of the invention select a corresponding modeling mode according to the operation of a user, establish a house frame 3D model according to the house type parameter information input by the user, and fuse decoration effect information selected by the user into the house frame 3D model to generate a decoration effect display model related to the house frame 3D model. And obtaining a decoration process, construction risk, decoration period and a decoration budget list for realizing the decoration effect display model through statistics, and generating a corresponding decoration scheme description file. Through the design, the house decoration effect display model meeting the requirements of the user can be generated on line, and convenience is brought to the user.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings identify some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic view of an application scenario of the decoration process control method and apparatus provided in the embodiment of the present invention.

Fig. 2 is a block schematic diagram of the server shown in fig. 1.

Fig. 3 is a schematic flow chart of a finishing process control method according to an embodiment of the present invention.

Fig. 4 is a schematic sub-step diagram of step S102 according to an embodiment of the present invention.

Fig. 5 is a schematic flow chart of a finishing process control method according to an embodiment of the present invention.

Fig. 6 is a schematic flow chart of a finishing process control method according to an embodiment of the present invention.

Fig. 7 is a schematic flow chart of a finishing process control method according to an embodiment of the present invention.

Fig. 8 is a connection block diagram of the decoration process control apparatus according to the embodiment of the present invention.

Fig. 9 is a connection block diagram of a house parameter obtaining module according to an embodiment of the present invention.

Reference numerals:

100-server, 110-memory, 111-operating system, 120-processor, 130-network module;

200-a first user terminal, 300-a second user terminal, 400-a network, 500-a decoration process control device;

510-selecting a module in a modeling mode;

520-a house parameter acquisition module, 521-a data receiving submodule, 522-a standardization submodule, 5221-an image normalization unit, 5222-a parameter normalization unit and 5223-a standard file generation unit;

530-3D model generation module, 540-decoration effect selection module, 550-3D effect diagram generation module, 560-decoration scheme generation module, 570-scheme sending module, 580-user confirmation module and 590-order issuing module; 5010-acceptance module; 5011-after sales management module.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

The decoration process control method and device provided by the embodiment of the invention can be applied to the application environment shown in fig. 1. As shown in fig. 1, the server 100 can be communicatively connected with a plurality of first user terminals 200 and second user terminals 300 through a network 400, so that the first user terminals 200 and the second user terminals 300 can perform data communication or interaction with the server 100 through the network 400.

In the embodiment of the present invention, the server 100 may be, but is not limited to, a web server, a data server, and the like. The network 400 may be, but is not limited to, a wired network 400 or a wireless network 400. The first user terminal 200 and the second user terminal 300 may be, but are not limited to, a Personal Computer (PC), a tablet PC, a smart phone, a Personal Digital Assistant (PDA), and the like.

Fig. 2 is a block diagram of a server 100 according to an embodiment of the present invention. As shown in fig. 2, the server 100 includes: the memory 110, the operating system 111, the processor 120, the network module 130, and the finishing process controlling apparatus 500.

The memory 110, the processor 120 and the network module 130 are electrically connected to each other directly or indirectly to realize data transmission or interaction. For example, the components may be electrically connected to each other via one or more communication buses or signal lines. The memory 110 stores therein a finishing process control device 500, and the finishing process control device 500 includes at least one software program and a module which can be stored in the memory 110 in the form of software or firmware (firmware), such as the finishing process control device 500 in the embodiment of the present invention, so as to execute various functional applications and data processing, that is, to implement the finishing process control method in the embodiment of the present invention. Random Access Memory (RAM), Read Only Memory (ROM), Programmable Read-Only Memory (PROM), Erasable Read-Only Memory (EPROM), electrically Erasable Read-Only Memory (EEPROM), and the like. The memory 110 is used for storing a program, and the processor 120 executes the program after receiving an execution instruction. Further, the operating system 111 in the storage 110 may include various software components and/or drivers for managing system tasks (such as memory management, storage device control, power management, etc.), and may communicate with various hardware or software components to provide an operating environment for other software components.

The processor 120 may be an integrated circuit chip having signal processing capabilities. The Processor 120 may be a general-purpose Processor including a Central Processing Unit (CPU), a Network Processor (NP), and the like. But may also be a Digital Signal Processor (DSP)), an Application Specific Integrated Circuit (ASIC), an off-the-shelf programmable gate array (FPGA) or other programmable logic device, discrete gate or transistor logic, discrete hardware components. The various methods, steps and logic blocks disclosed in the embodiments of the present invention may be implemented or performed. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.

The network module 130 is used for establishing a communication connection between the server 100 and an external communication terminal through a network, and implementing transceiving operation of network signals and data. The network signal may include a wireless signal or a wired signal.

It will be appreciated that the configuration shown in fig. 2 is merely illustrative and that server 100 may include more or fewer components than shown in fig. 2 or have a different configuration than shown in fig. 2. The components shown in fig. 2 may be implemented in hardware, software, or a combination thereof.

Please refer to fig. 3, which is a flowchart illustrating a finishing process control method applied to the server 100 shown in fig. 2 according to an embodiment of the present invention. The specific process and steps shown in fig. 3 will be described in detail below.

Step S101, receiving first request information sent by the first user terminal 200, and finding out a modeling function corresponding to the first request information from a pre-stored modeling function library.

The first user terminal 200 is suitable for users who need to design a house decoration scheme, such as owners and designers. Alternatively, the designer may perform identity authentication through the first user terminal 200 and send authentication information to the server 200, so that the server 100 can store the identity information in the user identity database and mark account information of the designer corresponding to the identity information. In implementation, the first user terminal 200 sends a first access request to the server 100, and the server 100 provides a first operation page to the first user terminal 200, where the first operation page is provided with a plurality of first tags, and each first tag stores first request information associated with a corresponding modeling function in the modeling function library of the server 100. That is, different first labels characterize different modeling methods.

For example, a house frame 3D model may be generated based on a user-provided plan and measured parameters corresponding to the plan. For another example, the user may generate the house frame 3D model by editing and combining sub-modules of various house structure 3D models in the server 100. As another example, the corresponding house frame 3D model is generated from only the house measurement parameters provided by the user. For another example, the user may generate or directly use a house frame 3D model of the user by performing fine-tuning on the house frame 3D model stored in the server 100, which is similar to the house type of the user. For another example, a hand-drawing interface may be provided for the user to draw the basic 3D house frame model online, and adjust the basic 3D house frame model according to the auxiliary parameters provided by the user to generate the final 3D house frame model.

And selecting a first label on the first operation page by the user, namely selecting a modeling method suitable for the user. The first user terminal 200, upon detecting an operation of the user selecting the first tag, transmits first request information stored in the first tag selected by the user to the server 100. After receiving the first request message, the server 100 searches a modeling function corresponding to the first request message in the modeling function library. It should be noted that the first operation page is a dynamic web page.

Step S102, receiving the subscriber type parameter information sent by the first user terminal 200.

After finding out the modeling function corresponding to the first request message, the server 100 sends a parameter input page corresponding to the modeling function to the first user terminal 200. Optionally, the parameter input page includes prompt information for prompting the user of a specific parameter that should be input, so as to prevent the content input by the user from being unrecognizable by the modeling function.

The first user terminal 200 acquires the user type parameter information input by the user on the parameter input page and transmits the user type parameter information to the server 100.

Step S103, processing the house type parameter information through the modeling function, generating a house frame 3D model, and sending the house frame 3D model to the first user terminal 200.

Specifically, the server 100 may generate a house frame 3D model by using the house type parameter information as an input value of the modeling function and operating the modeling function, and the server 100 may transmit the house frame 3D model to the first user terminal 200 for display.

Step S104, receiving the second request information sent by the first user terminal 200, and finding the decoration effect information corresponding to the second request information in a pre-stored decoration effect database.

After viewing the house frame 3D model, the user needs to add the decoration effect to the house frame 3D model to generate a decoration effect display model and a decoration scheme specification file matched with the decoration effect display model. Alternatively, the manner of adding the finishing effect to the house frame 3D model may be, but is not limited to, a bird's-eye view form or a roaming form. It should be noted that the decoration effect display model may include a global or local appearance effect map. The decoration scheme description file can comprise a visual construction section 3D model generated by the decoration effect display model, and the visual construction section 3D model displays all detailed layout conditions including wiring duct layout and the like in a house structure. The finishing protocol specification file may also include, but is not limited to, a supply cycle specification of the finishing product to be used and an acceptance instruction file based on the national industry standard so that the user can accept according to the acceptance instruction file after finishing.

In implementation, the first user terminal 200 sends a second access request to the server 100, and the server 100 provides a second operation page to the first user terminal 200, where the second operation page is provided with a plurality of second tags, and each second tag stores second request information associated with corresponding decoration effect information in the decoration effect database of the server 100. That is, different second labels characterize different modeling effectiveness information.

And selecting a second label on the second operation page by the user, namely selecting a modeling method. The first user terminal 200 transmits the second request information stored in the second tag selected by the user to the server 100 after detecting the operation of the user selecting the second tag. After receiving the second request information, the server 100 searches the decoration effect database for decoration effect information corresponding to the second request information. The decoration effect information comprises decoration budget, decoration style and house function, or overall design effect. That is, the decoration effect information may be combination information of a decoration budget, a decoration style and a house function, or may include only a single information of an overall design effect.

It should be noted that the second operation page is a dynamic web page.

And S105, generating a decoration effect display model of the house frame 3D model according to the decoration effect information.

According to different decoration effect information selected by the user, the server 100 generates different decoration effect display models.

For example, the user may select any one of the decoration budgets, any one of the decoration styles, and any one of the house functions to be combined, and use the combination of the decoration budget, the decoration style, and the house function as the decoration effect information, so that the server 100 merges the decoration effect information into the house frame 3D model and generates a decoration effect display model related to the house frame 3D model. For another example, the user may select an overall design effect as the decoration effect information, so that the server 100 merges the decoration effect information into the house frame 3D model and generates a decoration effect presentation model with respect to the house frame 3D model. It should be noted that, if the user is not satisfied with the generated decoration effect display model, a modification request may be sent to the server through the first user terminal and modified accordingly.

And S106, counting to obtain a decoration process, construction risk, a decoration period and a decoration budget list matched with the decoration effect information, and generating a decoration scheme description file comprising the decoration process, the construction risk, the decoration period and the decoration budget list.

In the implementation process, different decoration effect display models correspond to different decoration effect information. The server 100 may select the finishing product from the finishing product database according to different finishing effect information. Optionally, the server 100 further provides an actual decoration effect corresponding to each decoration product in the decoration product database, and the user may also select according to the actual decoration effect of each decoration product.

The server 100 records and counts each selected decoration product and the corresponding price, decoration process, construction risk and decoration period of the decoration product in real time, and generates a decoration scheme description file including the decoration process, construction risk, decoration period and decoration budget list.

It should be noted that the decoration product described herein may include a physical product such as a home appliance, wallpaper, etc., and may also include a service product such as a construction service, etc.

Step S107, sending the finishing scheme description file and the finishing effect display model on the 3D model of the house frame to the first user terminal 200.

After the server 100 transmits the finishing scheme specification file and the finishing effect presentation model with respect to the 3D model of the house frame to the first user terminal 200, the user can view through the first user terminal 200. Alternatively, if the user is not satisfied with the decoration effect display model, a decoration scheme modification request may be sent to the server 100 through the first user terminal 200, so as to modify the existing decoration effect display model and generate a new decoration scheme description file.

According to actual requirements, optionally, after the decoration effect display model is sent to the first user terminal 200, the server 100 may respond to a request of the first user terminal 200, convert the decoration effect display model into a file recognizable by a virtual reality system and send the file recognizable by the virtual reality system to the first user terminal 200, and a user can perform virtual reality experience by wearing a virtual reality display.

Alternatively, when modeling the house frame 3D model, the user may choose to model based on the house parameter information measured by the user and a plan view drawn based on the house parameter information.

Thus, as shown in fig. 4, the step S102 may include two substeps, step S201 and step S202, which are described in detail below.

Step S201, receiving the roof plan data sent by the first user terminal 200.

The user selects a first tab corresponding to a modeling method for 3D modeling by a plan view and related parameters in a first operation page, and transmits first request information in the first tab to the server 100. The server 100 finds a modeling function for modeling according to the floor plan and the related parameters according to the first request information, and sends a parameter input page corresponding to the modeling function to the first user terminal 200, prompting the user to input floor plan data. The user inputs the house plan data on the parameter input page to cause the first user terminal 200 to transmit the house plan data to the server 100. Wherein the parameter input page is a dynamic page.

Step S202, processing the house plane graph data to obtain a standard plane graph file, and using the standard plane graph file as the house type parameter information.

The house plan data is drawn by the user according to the house measurement parameters measured by the user, and the formats are not uniform, so that the server 100 is inconvenient to perform subsequent 3D modeling operation. Therefore, it is necessary to standardize the house floor plan data to obtain a standard floor plan file, and perform subsequent modeling operation using the standard floor plan file as the house type parameter information.

Alternatively, the server 100 may store the standard plan file in the measured plan database, so that other users can find out the plan matching with their own house type in the measured plan database as a reference. The designer user can also select plan data to be designed from the measured plan database to perform 3D modeling, and upload the design model and the corresponding decoration scheme to the decoration scheme database to be stored. It should be noted that, before storing the design model and the corresponding decoration scheme uploaded by the designer, the server 100 correlates the design model and the corresponding decoration scheme with the corresponding floor plan data. The designer may obtain corresponding remuneration when the design model and corresponding finishing scheme are adopted.

According to actual requirements, the house plan map data can comprise a house plan map and house measurement parameters, and the house plan map and the house measurement parameters need to be standardized respectively. Thus, optionally, the step of processing the house plan data into a standard plan file may comprise the sub-steps of:

carrying out normalization processing on the house plane graph to obtain a plane graph with a preset format; unifying the measurement units of the house measurement parameters to obtain standardized house measurement parameters; and generating the standard plane graph file according to the plane graph with the preset format and the normalized house measurement parameters.

Before normalization processing, the house plane graph and a preset coordinate system can be fused to generate a house plane graph based on the coordinate system, so that modeling can be performed on the basis of the coordinate system. The server 100 performs normalization processing on the house plane map based on the coordinate system to generate a plane map with a preset format. The preset format may be a file with a suffix name of ". bmp", ". jpg", ". gif", ". tga", ". pcx", ". raw", ". dwg", ". dxf", etc., but is not limited thereto. It should be understood that the file formats listed herein are exemplary only, and not limiting.

It should be noted that the preset format may be modified according to actual requirements.

The server 100 packages the plan with the preset format and the house measurement parameters after the unified measurement unit, generates a standard plan data file, and performs modeling according to the standard plan data file to obtain a house frame 3D model.

It should be noted that the room measurement parameters may be marked in the room plan, and in implementation, the server 100 obtains and stores the room measurement parameters through image recognition, or may be independent of the room plan, and the user inputs the room measurement parameters through the parameter input page to make the server 100 obtain and store the room measurement parameters.

Optionally, the step of obtaining a decoration budget list matched with the decoration effect information through statistics according to actual requirements may include the following sub-steps: and searching a decoration product matched with the decoration effect information in a pre-stored decoration product database, and acquiring information such as the price of the decoration product. A decoration product database is prestored in the server 100, and after the server 100 finds out the decoration effect information corresponding to the second request information, the corresponding decoration product needs to be selected from the decoration product database according to the decoration effect information, and the decoration product and the house frame 3D model are proportionally fused to generate a decoration effect display model related to the house frame 3D model.

The decoration product database is pre-stored with a purchase channel of each decoration product, wherein the purchase channel is a link address capable of purchasing the decoration product. The server 100 obtains and records price information of each selected decoration product from the decoration product database.

The server 100 also has a decoration process database prestored therein, and when the decoration process database is implemented, the server 100 searches the decoration process applicable to the selected decoration product in the decoration process database, integrates the decoration process applicable to the selected decoration product into a third operation page, and sends the third operation page to the first user terminal 200. The third operation page is provided with a plurality of third tags, and the third tags store third request information associated with corresponding finishing processes in the finishing process database of the server 100. The user selects a third tab corresponding to a finishing process applicable to the selected finishing product on the third operation page, and transmits third request information in the third tab to the server 100. The server 100 finds and records the finishing process corresponding to the third request information according to the third request information. The server 100 finally counts a decoration budget list of all decoration products required for finishing decoration.

As shown in fig. 5, after step S107, the finishing process management and control method may further include step S108 and step S109, which are described in detail below.

Step S108, detecting whether the confirmation information sent by the first user terminal 200 is received, and sending payment information to the first user terminal 200 when the confirmation information is received.

When the user confirms that the house frame 3D model and the finishing scheme specification file meet their requirements, a corresponding confirmation operation may be performed at the first user terminal 200 to cause the first user terminal 200 to transmit confirmation information to the server 100. After receiving the confirmation information, the server 100 calculates payment information according to the decoration budget list, and transmits the payment information to the first user terminal 200. The payment information may be, but is not limited to, a payment bill specification.

Step S109, detecting whether the paid information sent by the first user terminal 200 is received, and issuing decoration order information to the second user terminal 300 when the paid information is received.

Alternatively, the payment interface may provide a financial service link tag to access the corresponding financial service interface to provide a credit service for the user having difficulty in funding when the user makes a payment through the first user terminal 200. Optionally, the financial service interface may provide a link label of service interfaces of different banks according to actual requirements, so that the user can select the service interface according to the situation of the user.

If the user wants to adjust the decoration scheme after paying, a change request can be sent to the server 100 through the first user terminal 200, so that the server 100 adjusts the decoration scheme according to the user operation, and generates a new decoration effect display model and a decoration scheme description file. The server 100 transmits the new decoration effect display model and the decoration scheme specification file to the first user terminal 200 to reconfirm the user, and performs a corresponding decoration order issuing process after the reconfirmation. The decoration order issuing process and the steps after the process are consistent with the above contents, and are not described herein again.

When the user pays the decoration fee through the first user terminal 200, the first user terminal 200 sends the paid information to the server 100, and the server 100 receives the paid information sent by the first user terminal 200, and issues decoration order information to the second user terminal 300. Optionally, the decoration order information includes decoration product order information and construction order information. It should be noted that the second user terminal 300 is suitable for service providers such as a supplier and a finisher, wherein the supplier sells a finishing product and the finisher provides a construction service. When the supplier and the decorator view the decoration order information through the second user terminal 300, the corresponding order can be selected and received according to the conditions of the supplier and the decorator.

Optionally, the second user terminal 300 is further adapted to a supervisory management provider, which may provide a service for supervisory management of the finishing process. The service provider using the second user terminal 300 needs to pass identity authentication, and the authentication method is the same as that of the designer at the first user terminal 200. The decoration order information may further include supervision order information, so that a relevant professional can select to receive an order meeting the self condition through the second user terminal 300, and supervise the house decoration project corresponding to the order. In the supervision process, construction progress information may be periodically transmitted to the server 100 through the second user terminal 300. According to actual requirements, the construction progress information may include, but is not limited to, video recording information of the site construction situation. The server 100 receives and stores the construction progress information so that the owner can access the construction progress information through the first user terminal 200.

Optionally, the second user terminal 300 is further adapted to a logistics service provider, which provides a service of delivering the decoration product. Therefore, the decoration order information may further include logistics order information. In practice, the logistics service provider can upload the supply information to the server 100 through the second user terminal 300, so that the first user terminal 200 can access the server 100 through the network 400 and view the supply information. The supply information may include, but is not limited to, a shipping schedule, a product quantity, and a receiving method.

Optionally, as shown in fig. 6, the decoration process management and control method may further include two steps, i.e., step S110 and step S111, which are described in detail below.

Step S110 detects whether acceptance information sent by the first user terminal 200 is received.

After the whole decoration is completed, the user can check and accept the house after the decoration is completed according to the description content in the decoration scheme description file, and if the house meets the requirement, the corresponding checking and accepting operation is performed on the first user terminal 200, so that the first user terminal 200 sends checking and accepting information to the server 100.

And step S111, marking the decoration order as finished when the acceptance information is received, and sending an after-sale management notice to the second user terminal.

When the server 100 receives the acceptance information, the corresponding decoration order can be marked as a completed state in the database. Meanwhile, the server 100 transmits an after-sales management notice to the second user terminal 300, so that the corresponding supplier, construction service provider, etc. updates the after-sales service information in the server 100, so as to contact the corresponding merchant when a problem occurs in the house.

Optionally, as shown in fig. 6, the decoration process management and control method may further include three steps, namely step S112, step S113 and step S114, which are described in detail as follows.

And step S112, acquiring the sales volume of each decoration product in the decoration product library and the selected times of each decoration effect information in the decoration effect database, and counting.

And S113, arranging the decoration products according to the order of sales volume from high to low according to the statistical result.

And step S114, arranging the decoration effect information according to the order of the selected times from high to low according to the statistical result.

Alternatively, the server 100 may perform data acquisition and statistics according to regions when acquiring the sales volume of each decoration product in the decoration product library and the number of times of selecting each decoration effect information in the decoration effect database. For example: and obtaining and counting the sales volume of each decoration product adopted by the users in different province ranges and the type and the number of the selected decoration effect information, thereby obtaining the popularity of different decoration products and decoration effects in different provinces. Optionally, the server may also, but is not limited to, perform data acquisition and statistics in different cities and counties to obtain popularity of different decoration products and decoration effects in different cities and counties.

During implementation, a supplier and a designer who provides design service on line can calculate the popularity of each decoration product and decoration effect information according to the arrangement result, so that the supplier and the designer can correspondingly adjust according to the requirements of users.

Alternatively, when finishing is completed, the second user terminal 300 transmits completion confirmation information to the server 100 to cause the server 100 to transmit notification information toward the first user terminal 200. After receiving the notification information, the first user obtains an acceptance completion confirmation trigger input by the user and sends the trigger to the server 100, so that the server 100 marks the order as completed in the database.

Through the design, the decoration scheme design, the decoration product purchasing, the construction and the decoration effect acceptance are integrated into a complete system, so that the management and the control of the whole decoration process are facilitated, and convenience is provided for decoration of a user.

It should be particularly noted that the first user terminal 100 and the second user terminal 200 provided in the embodiment of the present invention may also be, but are not limited to, servers of any other management system, control system, or data analysis system. When the server of any other system obtains the corresponding access right, the server can communicate with the server 100 in the embodiment of the present invention to access different databases in the server 100, so as to provide a decoration industry data sharing platform for various industries, so that other people or industries needing to use decoration data can obtain required data from the database of the server 100 provided in the embodiment of the present invention.

The embodiment of the present invention further provides a decoration process management and control apparatus 500, which is applied to a server 100, where the server 100 can be accessed by a plurality of first user terminals 200 through a network 400. As shown in fig. 7, the decoration process management and control apparatus 500 includes a modeling manner selecting module 510, a house parameter obtaining module 520, a 3D model generating module 530, a decoration effect selecting module 540, a 3D effect diagram generating module 550, a decoration scheme generating module 560, and a scheme sending module 570.

The modeling manner selecting module 510 is configured to receive first request information sent by the first user terminal 200, and find a modeling function corresponding to the first request information in a pre-stored modeling function library. The detailed description of the modeling manner selecting module 510 can refer to the description of step S101 shown in fig. 3 in the embodiment of the present invention. That is, step S101 may be performed by the modeling manner selecting module 510.

The house parameter obtaining module 520 is configured to receive the user type parameter information sent by the first user terminal 200. The detailed description of the house parameter obtaining module 520 may refer to the description of step S102 shown in fig. 3. That is, step S102 may be performed by the house parameter obtaining module 520.

The 3D model generating module 530 is configured to process the user type parameter information through the modeling function, generate a 3D model of the house frame, and send the 3D model to the first user terminal 200. The detailed description of the 3D model generation module 530 may refer to the description of step S103 shown in fig. 3 in the embodiment of the present invention. That is, step S103 may be performed by the 3D model generation module 530.

The decoration effect selecting module 540 is configured to receive the second request information sent by the first user terminal 200, and search the decoration effect information corresponding to the second request information in a pre-stored decoration effect database. The decoration effect information comprises a decoration budget, a decoration style and house functions or an overall design effect. The detailed description of the decoration effect selecting module 540 may refer to the description of the embodiment of the invention on S104 shown in fig. 3. That is, the step S104 may be performed by the decoration effect selecting module 540.

The 3D effect map generating module 550 is configured to generate a decoration effect display model related to the 3D house frame model according to the decoration effect information. The detailed description about the 3D effect map generating module 550 may refer to the description of step S105 shown in fig. 3 in the embodiment of the present invention. That is, step S105 may be performed by the 3D effect map generating module 550.

The decoration scheme generation module 560 is configured to count a decoration process, a construction risk, a decoration period, and a decoration budget list that are matched with the decoration effect information, and generate a decoration scheme description file including the decoration process, the construction risk, the decoration period, and the decoration budget list. The decoration scheme generating module 560 may refer to the description of step S106 shown in fig. 3 in the embodiment of the present invention. That is, step S106 may be performed by the finishing scheme generating module 560.

The scheme transmitting module 570 is configured to transmit the finishing scheme specification file and the finishing effect presentation model with respect to the 3D model of the house frame to the first user terminal 200. The detailed description of the scheme sending module 570 refers to the description of step S107 shown in fig. 3 in the embodiment of the present invention. That is, step S107 may be performed by the scheme transmission module 570.

Alternatively, the server 100 may be accessed by a plurality of second user terminals 300 through the network 400, and the finishing process managing and controlling apparatus 500 may further include a user confirmation module 580, an order issuing module 590, an acceptance module 5010, and an after-sales management module 5011.

The user confirmation module 580 is configured to detect whether confirmation information sent by the first user terminal 200 is received, and send payment information to the first user terminal 200 when the confirmation information is received. The detailed description of the user confirmation module 580 may refer to the description of step S108 shown in fig. 5 in the embodiment of the present invention. That is, step S108 may be performed by the user confirmation module 580.

The order issuing module 590 is configured to detect whether paid information sent by the first user terminal 200 is received, and issue decoration order information to the second user terminal 300 when the paid information is received, where the decoration order information includes decoration product order information, construction order information, supervision management order information, and logistics order information. The detailed description of the order issuing module 590 refers to the description of step S109 shown in fig. 5 in the embodiment of the present invention. That is, step S109 may be performed by the order issuing module.

The acceptance module 5010 is configured to detect whether acceptance information sent by the first user terminal is received. The detailed description about the acceptance module 5010 can refer to the detailed description about step S110 in fig. 6. That is, step S110 may be performed by the acceptance module 5010.

The after-sale management module 5011 is configured to mark the decoration order as complete when receiving the acceptance information, and send an after-sale management notice to the second user terminal. The detailed description about the after-sales management module 5011 can refer to the detailed description about step S111 in fig. 6. That is, step S111 may be performed by the after-sales management module 5011.

As shown in fig. 7, optionally, the room parameter obtaining module 520 may include a data receiving sub-module 521 and a normalizing sub-module 522.

The data receiving submodule 521 is configured to receive the roof plan data sent by the first user terminal 200. The description of the data receiving submodule 521 may refer to the description of step S201 shown in fig. 4 in the embodiment of the present invention. That is, step S201 may be performed by the data receiving submodule 521.

The normalization submodule 522 is configured to process the house plane map data to obtain a standard plane map file, and use the standard plane map file as the house type parameter information. The detailed description of the normalization sub-module 522 can refer to the description of step S202 shown in fig. 4 in the embodiment of the present invention. That is, step S202 may be performed by the normalization sub-module 522.

Optionally, the floor plan data includes floor plan and house measurement parameters, and thus the normalization submodule 522 may include an image normalization unit 5221, a parameter normalization unit 5222 and a standard file generation unit 5223.

The image normalization unit 5221 is configured to normalize the house plan map to obtain a plan map in a preset format.

The parameter normalization unit 5222 is configured to unify the measurement units of the room measurement parameters to obtain normalized room measurement parameters.

The standard file generating unit 5223 is configured to generate the standard plane graph file according to the plane graph in the preset format and the normalized house measurement parameters.

For the detailed description of the image normalization unit 5221, the parameter normalization unit 5222 and the standard file generation unit 5223, reference may be made to the description of the relevant steps in the embodiment of the present invention, which is not repeated herein.

In summary, the decoration process control method and the device provided by the embodiment of the invention can generate the decoration effect display model and the decoration scheme description file on line according to the user requirements, so that the design of the decoration scheme is not limited by the level of a designer. The decoration scheme design, decoration product purchase, construction, effect acceptance and after-sale service are integrated into a complete system, so that the decoration process is convenient to manage, the complex interference flow in the house decoration process is avoided, and the decoration by a user is more convenient.

The functions, if implemented in the form of software functional modules and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention may be embodied in the form of a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes. It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (8)

1. A decoration process control method is applied to a server, and the server can be accessed by a plurality of first user terminals through a network, and is characterized by comprising the following steps:

receiving first request information sent by a first user terminal, and searching a modeling function corresponding to the first request information in a pre-stored modeling function library;

receiving user type parameter information sent by a first user terminal, wherein the user type parameter information comprises a house plane graph and a measurement parameter corresponding to the house plane graph, or comprises a submodule of a preset house structure 3D model, or comprises a house measurement parameter, or a house frame 3D model similar to the preset house type, or obtains the house frame 3D model and a corresponding auxiliary parameter through a hand-drawing interface;

when the house type parameter information comprises a house plane graph and a measurement parameter corresponding to the house plane graph, fusing the house plane graph with a preset coordinate system to generate a house plane graph based on the preset coordinate system, and performing normalization processing on the house plane graph based on the preset coordinate system to obtain a plane graph with a preset format; unifying the measurement units of the measurement parameters corresponding to the house plan graph to obtain standardized house measurement parameters; generating a standard plane graph file according to the plane graph with the preset format and the normalized house measurement parameters, and modeling according to the standard plane graph file through the modeling function to obtain a house frame 3D model and generate a house frame 3D model;

when the house type parameter information comprises sub-modules of a preset house structure 3D model, editing and combining the sub-modules of the preset house structure 3D model through the modeling function so as to generate a house frame 3D model;

when the house type parameter information comprises house measurement parameters, generating a corresponding house frame 3D model through the modeling function and the house measurement parameters;

when the house type parameter information comprises a house frame 3D model similar to a preset house type, fine tuning is carried out through the modeling function and the house frame 3D model similar to the preset house type to generate a house frame 3D model;

when the house type parameter information comprises a house frame 3D model and corresponding auxiliary parameters obtained through a hand-drawing interface, obtaining a basic house frame 3D model drawn on line by a user through the modeling function and the hand-drawing interface, and adjusting according to the obtained auxiliary parameters to generate a final house frame 3D model;

transmitting the generated 3D model of the house frame to a first user terminal;

receiving second request information sent by a first user terminal, and searching decoration effect information corresponding to the second request information in a pre-stored decoration effect database, wherein the decoration effect information comprises decoration budget, decoration style and house function or overall design effect;

generating a decoration effect display model about the 3D model of the house frame according to the decoration effect information; and

calculating and counting to obtain a decoration process, construction risk, a decoration period and a decoration budget list matched with the decoration effect information, and generating a decoration scheme description file comprising the decoration process, the construction risk, the decoration period and the decoration budget list;

transmitting the finishing scheme description file and a finishing effect display model about the house frame 3D model to the first user terminal;

responding to a request of the first user terminal, converting the decoration effect display model into a file recognizable by a virtual reality system and sending the file recognizable by the virtual reality system to the first user terminal so that a user can perform virtual reality experience by wearing a virtual reality display.

2. The decoration process management and control method according to claim 1, wherein the step of counting to obtain a decoration budget list matched with the decoration effect information comprises:

searching a decoration product matched with the decoration effect information in a pre-stored decoration product database, and acquiring the price information of the decoration product;

searching a decoration process suitable for the decoration product in a prestored decoration process database and sending the decoration process to a first user terminal;

receiving third request information sent by a first user terminal, and searching a decoration process corresponding to the third request information in a decoration process applicable to the decoration product;

and calculating a required decoration budget according to the price information of the decoration product and the decoration process corresponding to the third request information, and generating the decoration budget list.

3. A finishing process management and control method according to claim 1 or 2, wherein the server is accessible to a plurality of second user terminals through a network, and after the finishing plan specification file and the finishing effect presentation model with respect to the house frame 3D model are transmitted to the first user terminal, the method further comprises:

detecting whether confirmation information sent by the first user terminal is received or not, and sending payment information to the first user terminal when the confirmation information is received; and

and detecting whether paid information sent by the first user terminal is received or not, and issuing decoration order information to a second user terminal when the paid information is received, wherein the decoration order information comprises decoration product order information, construction order information, supervision management order information and logistics order information.

4. The finishing process management and control method according to claim 3, further comprising:

detecting whether acceptance information sent by a first user terminal is received;

and marking the decoration order as finished when the acceptance information is received, and sending an after-sale management notice to the second user terminal.

5. The finishing process management and control method according to claim 4, further comprising:

obtaining the sales volume of each decoration product in the decoration product library and the selected times of each decoration effect information in the decoration effect database and carrying out statistics;

arranging the decoration products according to the order of sales volume from high to low according to the statistical result; and

and arranging the decoration effect information according to the order of the selected times from high to low according to the statistical result.

6. A management and control device for a decoration process is applied to a server, and the server can be accessed by a plurality of first user terminals through a network, and is characterized by comprising a modeling mode selection module, a house parameter acquisition module, a 3D model generation module, a decoration effect selection module, a 3D effect graph generation module, a decoration scheme generation module and a sending module;

the modeling mode selection module is used for receiving first request information sent by a first user terminal and searching a modeling function corresponding to the first request information in a prestored modeling function library;

the house parameter acquisition module is used for receiving house type parameter information sent by a first user terminal, wherein the house type parameter information comprises a house plane graph and a measurement parameter corresponding to the house plane graph, or comprises a submodule of a preset house structure 3D model, or comprises a house measurement parameter, or a house frame 3D model similar to the preset house type, or acquires a house frame 3D model and a corresponding auxiliary parameter through a hand-drawn interface;

the 3D model generation module is configured to: when the house type parameter information comprises a house plane graph and a measurement parameter corresponding to the house plane graph, fusing the house plane graph with a preset coordinate system to generate a house plane graph based on the preset coordinate system, and performing normalization processing on the house plane graph based on the preset coordinate system to obtain a plane graph with a preset format; unifying the measurement units of the measurement parameters corresponding to the house plan graph to obtain standardized house measurement parameters; generating a standard plane graph file according to the plane graph with the preset format and the normalized house measurement parameters, and modeling according to the standard plane graph file through the modeling function to obtain a house frame 3D model and generate a house frame 3D model; when the house type parameter information comprises sub-modules of a preset house structure 3D model, editing and combining the sub-modules of the preset house structure 3D model through the modeling function so as to generate a house frame 3D model; when the house type parameter information comprises house measurement parameters, generating a corresponding house frame 3D model through the modeling function and the house measurement parameters; when the house type parameter information comprises a house frame 3D model similar to a preset house type, fine tuning is carried out through the modeling function and the house frame 3D model similar to the preset house type to generate a house frame 3D model; when the house type parameter information comprises a house frame 3D model and corresponding auxiliary parameters obtained through a hand-drawing interface, obtaining a basic house frame 3D model drawn on line by a user through the modeling function and the hand-drawing interface, and adjusting according to the obtained auxiliary parameters to generate a final house frame 3D model; transmitting the generated 3D model of the house frame to a first user terminal;

the decoration effect selection module is used for receiving second request information sent by the first user terminal, and searching decoration effect information corresponding to the second request information in a prestored decoration effect database, wherein the decoration effect information comprises decoration budget, decoration style and house function or overall design effect;

the 3D effect graph generating module is used for generating a decoration effect display model of the house frame 3D model according to the decoration effect information;

the decoration scheme generation module is used for counting decoration processes, construction risks, decoration period and a decoration budget list matched with the decoration effect information and generating a decoration scheme description file comprising the decoration processes, the construction risks, the decoration period and the decoration budget list;

the sending module is used for sending the decoration scheme description file and the decoration effect display model related to the house frame 3D model to the first user terminal;

the sending module is further configured to: responding to a request of the first user terminal, converting the decoration effect display model into a file recognizable by a virtual reality system and sending the file recognizable by the virtual reality system to the first user terminal so that a user can perform virtual reality experience by wearing a virtual reality display.

7. The finishing process management and control device according to claim 6, wherein the server is accessible to a plurality of second user terminals through a network, and the finishing process management and control device further comprises a user confirmation module and an order issuance module;

the user confirmation module is used for detecting whether confirmation information sent by a first user terminal is received or not, and sending payment information to the first user terminal when the confirmation information is received;

the order issuing module is used for detecting whether paid information sent by a first user terminal is received or not, and issuing decoration order information to a second user terminal when the paid information is received, wherein the decoration order information comprises decoration product order information, construction order information, supervision and management order information and logistics order information.

8. The finishing process management and control device according to claim 7, further comprising an acceptance module and an after-sales management module;

the acceptance module is used for detecting whether acceptance information sent by the first user terminal is received;

and the after-sale management module is used for marking the decoration order as finished when the acceptance information is received and sending an after-sale management notice to the second user terminal.

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