CN110727974B

CN110727974B - Data processing method, apparatus, computer device and readable storage medium

Info

Publication number: CN110727974B
Application number: CN201810678999.3A
Authority: CN
Inventors: 张海明
Original assignee: Xi'an Sea2 Network Technology Co ltd
Current assignee: Nanjing Runshijing Environmental Engineering Co ltd
Priority date: 2018-06-27
Filing date: 2018-06-27
Publication date: 2023-10-27
Anticipated expiration: 2038-06-27
Also published as: CN110727974A

Abstract

The invention relates to a data processing method, a data processing device, a computer device and a readable storage medium. The method comprises the following steps: determining available space information of the design environment model according to the input attribute information of the design environment model; according to the input functional area demand information and the available space information, a plurality of functional area placement combinations are determined; each function area placement combination comprises a plurality of function areas associated with positions, and the function area demand information carries the number of the function areas and the types of the function areas required by a user; according to a preset first screening strategy, determining a target functional area placement combination with the largest comfort parameter from the plurality of functional area placement combinations; and outputting a design result according to the target functional area placement combination and filling models required by each functional area in the target functional area placement combination. The invention greatly improves the design efficiency of the designer, and the matching degree between the output design result and the user requirement is higher.

Description

Data processing method, apparatus, computer device and readable storage medium

Technical Field

The present invention relates to the field of computer technologies, and in particular, to a data processing method, apparatus, computer device, and readable storage medium.

Background

With the continuous development of social economy, people have increasingly higher requirements on aesthetic and comfort aspects of living areas, office areas and other areas, so that users pay more attention to design schemes output by designers.

At present, when a designer designs a decoration scheme for a user, the main design mode is as follows: the designer relies on computer software and the subjective consciousness of the designer to carry out the planning design of the whole room, thereby outputting a corresponding design scheme.

However, the efficiency of the conventional technical designer in designing the design is low, and the matching degree of the output design and the user's requirement is poor.

Disclosure of Invention

Based on this, it is necessary to provide a data processing method, apparatus, computer device and readable storage medium for the problems that the efficiency of the designer in designing the design is low and the matching degree of the output design and the user's demand is poor.

In a first aspect, an embodiment of the present invention provides a data processing method, including:

determining available space information of the design environment model according to the input attribute information of the design environment model;

according to the input functional area demand information and the available space information, a plurality of functional area placement combinations are determined; each function area placement combination comprises a plurality of function areas associated with positions, and the function area demand information carries the number of the function areas and the types of the function areas required by a user;

According to a preset first screening strategy, determining a target functional area placement combination with the largest comfort parameter from the plurality of functional area placement combinations;

and outputting a design result according to the target functional area placement combination and filling models required by each functional area in the target functional area placement combination.

According to the data processing method provided by the embodiment, the computer equipment determines available space information of the design environment model according to the input attribute information of the design environment model, determines a plurality of functional area placement combinations according to the input functional area demand information and the available space information, then determines a target functional area placement combination with the largest comfort parameter from the plurality of functional area placement combinations according to a preset first screening strategy, and outputs a design result according to the target functional area placement combination and a filling model required by each functional area in the target functional area placement combination. In the whole scheme design process, the starting point of scheme design is based on the functional requirement of a user, and the screening strategy for screening the target functional area placement combination is also based on whether the comfort requirement of the user can be met, so that the matching degree between the design result finally output by the computer equipment and the user requirement is higher. In addition, the whole design process is automatically designed by the computer equipment, so that the human participation process is reduced, the design efficiency of the designer is greatly improved, the influence of subjective consciousness of the designer on the design result is reduced, and the matching degree between the design result and the user requirement is further improved.

In one embodiment, the determining available space information of the design environment model according to the input attribute information of the design environment model includes:

acquiring input attribute information of an existing model in the design environment model;

determining available space information of the design environment model and environment characteristic information of the design environment model according to the attribute information of the existing model;

wherein the attribute information of the existing model includes: at least two of a building type to which the existing model belongs, a room type of the existing model, a system type to which the existing model belongs, geometric position information of the existing model, physical information of the existing model, and actual construction characteristics of the existing model.

According to the data processing method provided by the embodiment, the computer equipment determines available space information of the design environment model and environment characteristic information of the design environment model through attribute information of the existing model in the design environment model. The method refers to the attribute information of the existing model in the design environment model, so that the accuracy of the available space information of the design environment model and the environment characteristic information of the design environment model determined by the computer equipment is higher, and an accurate data basis is provided for the subsequent scheme design, and therefore, the matching degree between a design result and user requirements is further improved. In addition, in the subsequent scheme design, the accurate data basis can also improve the space utilization rate of the design environment model.

In one embodiment, the determining a plurality of functional area placement combinations according to the input functional area requirement information and the available space information includes:

determining the number of functional areas which can be placed in the design environment model according to the functional area demand information and the available space information;

determining a plurality of available functional areas according to the number of the functional areas and the priority of each functional area;

and determining the placement combination of the plurality of functional areas according to the plurality of available functional areas and the available space information.

In one embodiment, the determining, according to the functional area requirement information and the available space information, the number of functional areas that can be put in the design environment model includes:

determining a basic functional area and an alternative functional area according to the functional area demand information; the basic functional area is an area for guaranteeing basic requirements of users;

judging whether the total occupied area of the basic functional area meets the size requirement of the available space information or not, and obtaining a judging result;

and determining the number of functional areas which can be placed in the design environment model according to the judging result.

In one embodiment, the determining the plurality of functional area placement combinations according to the plurality of available functional areas and the available space information includes:

and determining the placement combination of the plurality of functional areas according to the plurality of available functional areas, the available space information and the attribute information of the existing model.

and determining the placement combination of the plurality of functional areas according to the plurality of available functional areas, the available space information and the environment characteristic information of the design environment model.

According to the data processing method provided by the embodiment, the computer equipment determines the number of the functional areas which can be placed in the design environment model according to the functional area demand information and the available space information, determines a plurality of available functional areas according to the number of the functional areas and the priority of each functional area, and then determines the placement combination of the plurality of functional areas according to the plurality of available functional areas and the available space information. When the arrangement combination of the plurality of functional areas is determined, the available space of the design environment model is combined, and the priority of each functional area required by a user is combined, so that the matching degree of the final design result and the user requirement is higher, and the space utilization rate of the design environment model is improved.

In one embodiment, the determining, according to a preset first screening policy, a target functional area placement combination with a maximum comfort parameter from the multiple functional area placement combinations includes:

calculating the value of the comfort parameter corresponding to each functional area placement combination; wherein, the value of the comfort parameter is equal to the sum of the weighting parameters corresponding to each functional area in the functional area placement combination; the weighting parameters corresponding to the functional areas are equal to the sum of the weights corresponding to the placement positions of the filling models in the functional areas;

and determining the functional area placement combination with the largest value of the comfort parameter as the target functional area placement combination.

According to the data processing method provided by the embodiment, the computer equipment calculates the value of the comfort parameter corresponding to each functional area placement combination, and determines the functional area placement combination with the largest value of the comfort parameter as the target functional area placement combination. Because the computer equipment determines the target functional area placement combination according to the value of the comfort parameter corresponding to each functional area placement combination, and the maximum value of the comfort parameter represents that the comfort requirement of the user can be met, the target functional area placement combination determined according to the screening strategy can meet the comfort requirement of the user, and the matching degree between the design result and the user requirement is further improved.

In one embodiment, the outputting the design result according to the target functional area placement combination and the filling model required by each functional area in the target functional area placement combination includes:

determining various model filling combinations according to attribute information of filling models required by each functional area in the target functional area placing combinations; each model filling combination comprises a plurality of models which can be filled into the target functional area placement combination;

and screening from the plurality of model filling combinations according to a preset second screening strategy to obtain a target model filling combination, filling the target model filling combination into the target functional area placement combination, and outputting the design result.

According to the data processing method provided by the embodiment, the computer equipment determines a plurality of model filling combinations according to the attribute information of the filling models required by each functional area in the target functional area placing combinations, screens the plurality of model filling combinations to obtain target model filling combinations according to a preset second screening strategy, fills the target model filling combinations into the target functional area placing combinations, and outputs a design result. Because the second screening strategy is other screening strategies based on meeting the basic comfort requirement of the user, and the computer equipment can determine the target model filling combination based on the second screening strategy, the output design result not only meets the comfort requirement of the user, but also meets other requirements (such as price requirement, style requirement and the like) of the user, and the matching degree between the design result and the user requirement is further improved.

In one embodiment, the outputting the design result according to the target functional area placement combination and the filling model required by each functional area in the target functional area combination includes:

determining a first filling model required by each functional area in the target functional area placement combination according to each functional area in the target functional area placement combination and a preset mapping relation; the mapping relation comprises the corresponding relation between different functional areas and each filling model;

and filling the first filling models corresponding to the functional areas into the target functional area placement combination, and outputting the design result.

According to the data processing method provided by the embodiment, the computer equipment can determine the first filling model required by each functional area in the target functional area placement combination according to the preset mapping relation table, fill the first filling model corresponding to each functional area into the target functional area placement combination, and output a design result. The computer equipment can directly determine the first filling model required by each functional area in the target functional area placement combination through the preset mapping relation table, so that the processing process of the computer equipment is greatly simplified, and the design efficiency of designers is further improved.

In one embodiment, after the outputting of the design result, the method further comprises at least one of:

determining whether the output design result is correct or not according to a preset design result quantification strategy, determining the degree of merit when the output design result is correct, and modifying the design result according to a preset design result modification strategy;

wherein the design result quantization strategy and the design result modification strategy each comprise at least one of the following parameters: decoration national standard parameters, industry standard parameters, production attributes of filling models in the design environment model, processing attributes of filling models in the design environment model and installation attributes of filling models in the design environment model.

According to the data processing method provided by the embodiment, after the computer equipment outputs the design result, whether the output design result is correct or not and the quality degree when the output design result is correct or not can be determined according to the preset design result quantification strategy, so that the matching degree between the output design result and the user requirement can be ensured, the quality degree of the output design result can be clarified, and the later optimization research and development can be facilitated; in addition, when the design result needs to be modified, the computer equipment can also automatically modify the design result according to a preset design result modification strategy, so that the repeated operation of a designer is simplified, the modification difficulty of the designer is reduced, and the working efficiency of the designer is greatly improved.

In one embodiment, the outputting the design result includes:

outputting the design result according to the scheme display requirement input by the user; wherein, the design result carries design budget information.

According to the data processing method provided by the embodiment, the computer equipment can display the requirement according to the scheme input by the user and output the design result, so that the output design result meets the requirement of the user, and the matching degree between the design result and the requirement of the user is further improved.

In one embodiment, the functional area includes: at least one of sleeping area, sanitary area, video-audio area, body-building area, reading area, arrangement area and coat-hat area.

In a second aspect, an embodiment of the present invention provides a data processing apparatus, including:

the first determining module is used for determining available space information of the design environment model according to the input attribute information of the design environment model;

the second determining module is used for determining a plurality of functional area placement combinations according to the input functional area demand information and the available space information; each function area placement combination comprises a plurality of function areas associated with positions, and the function area demand information carries the number of the function areas and the types of the function areas required by a user;

The screening module is used for determining a target functional area placement combination with the largest comfort parameter from the functional area placement combinations according to a preset first screening strategy;

and the scheme processing module is used for outputting a design result according to the target functional area placement combination and filling models required by each functional area in the target functional area placement combination.

In a third aspect, an embodiment of the present invention provides a computer device, including a memory and a processor, the memory storing a computer program, the processor implementing the following steps when executing the computer program:

In a fourth aspect, embodiments of the present invention provide a computer readable storage medium having stored thereon a computer program which when executed by a processor performs the steps of:

The data processing apparatus, the computer device and the readable storage medium provided in this embodiment can enable the computer device to determine available space information of a design environment model according to input attribute information of the design environment model, determine a plurality of functional area placement combinations according to input functional area demand information and available space information, then determine a target functional area placement combination with a maximum comfort parameter from the plurality of functional area placement combinations according to a preset first screening policy, and output a design result according to the target functional area placement combination and a filling model required by each functional area in the target functional area placement combination. In the whole scheme design process, the starting point of scheme design is based on the functional requirement of a user, and the screening strategy for screening the target functional area placement combination is also based on whether the comfort requirement of the user can be met, so that the matching degree between the design result finally output by the computer equipment and the user requirement is higher. In addition, the whole design process is automatically designed by the computer equipment, so that the human participation process is reduced, the design efficiency of the designer is greatly improved, the influence of subjective consciousness of the designer on the design result is reduced, and the matching degree between the design result and the user requirement is further improved.

Drawings

FIG. 1a is a schematic diagram illustrating an internal structure of a computer device according to an embodiment;

FIG. 1 is a flow chart of a data processing method according to an embodiment;

FIG. 2 is a flow chart of a data processing method according to another embodiment;

FIG. 3 is a flowchart of another embodiment of a data processing method;

FIG. 4 is a functional area placement combination according to another embodiment;

FIG. 5 is a flowchart of another embodiment of a data processing method;

FIG. 6 is a flowchart of another embodiment of a data processing method;

FIG. 7 is a flowchart of another embodiment of a data processing method;

FIG. 8 is a flowchart of another embodiment of a data processing method;

FIG. 9 is a schematic diagram of a data processing apparatus according to an embodiment;

FIG. 10 is a schematic diagram of a data processing apparatus according to another embodiment;

FIG. 11 is a schematic diagram of a data processing apparatus according to another embodiment;

FIG. 12 is a schematic diagram of a data processing apparatus according to another embodiment;

FIG. 13 is a schematic diagram of a data processing apparatus according to another embodiment;

FIG. 14 is a schematic diagram of a data processing apparatus according to another embodiment;

Fig. 15 is a schematic structural diagram of a data processing apparatus according to another embodiment.

Detailed Description

The data processing method provided by the embodiment of the invention can be applied to the computer equipment shown in the figure 1 a. The computer device comprises a processor, a memory, and a computer program stored in the memory, wherein the processor is connected through a system bus, and when executing the computer program, the processor can execute the steps of the method embodiments described below. Optionally, the computer device may further comprise a network interface, a display screen and an input means. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device includes a non-volatile storage medium, which stores an operating system and a computer program, an internal memory. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The network interface of the computer device is used for communicating with an external terminal through a network connection. Optionally, the computer device may be a server, a PC, a personal digital assistant, other terminal devices, for example, a PAD, a mobile phone, etc., or a cloud or remote server, and the embodiment of the present invention does not limit a specific form of the computer device.

In the conventional indoor scheme design, a designer usually performs indoor scheme design according to subjective consciousness of the designer through computer software, so as to output a design result of the scheme. However, the design result output by the conventional design method cannot meet the actual requirement of the user, the matching degree with the actual requirement of the user is poor, and the design efficiency of the designer is low. In addition, when the design scheme is adopted, a designer mainly relies on personal experience and habit to design, so that the indoor space is easy to be unreasonably planned, and the indoor space is wasted. To this end, embodiments of the present invention provide a data processing method, apparatus, computer device, and readable storage medium, which aim to solve the above technical problems of the conventional technology.

It should be noted that, the execution body of the method embodiments described below may be a data processing apparatus, and the apparatus may be implemented by software, hardware, or a combination of software and hardware, which is part or all of the computer device described above. The following method embodiments are described taking the implementation subject as a computer device as an example.

The following describes the technical scheme of the present invention and how the technical scheme of the present invention solves the above technical problems in detail with specific embodiments. The following embodiments may be combined with each other, and the same or similar concepts or processes may not be described in detail in some embodiments. Embodiments of the present invention will be described below with reference to the accompanying drawings.

Fig. 1 is a flow chart of a data processing method according to an embodiment. The embodiment relates to a specific process how the computer device automatically outputs the design result according to the attribute information of the design environment model and the functional area requirement information of the user. As shown in fig. 1, the method may include:

s101, determining available space information of the design environment model according to the input attribute information of the design environment model.

Specifically, the design environment model refers to an environment model that needs to be designed for functional planning. The design environment model may be a larger region space or a smaller region space. Taking the building type of the design environment model as a residential building as an example, the design environment model can be a house with a few rooms and a few halls, or can be a certain room in the house with a few rooms and a few halls. The attribute information of the design environment model may include self attribute information of the design environment model, and may also include attribute information of an existing model within the design environment model. By way of example, the self attribute information of the design environment model may include a building type of the design environment model (e.g., the building type may be a public building, a mall building, a residential building, a write building, an entertainment building, etc.), a building area of the design environment model, a structural diagram of the design environment model, and the like. The attribute information of the design environment model may be input to the computer device by a text input method, or may be input to the computer device by a voice input method, which is not limited in this embodiment. The available space information may include the size of the available space, and may further include characteristics of the available space, including the electromechanical specification of the available space, construction characteristics, and types of models that the available space can accommodate.

In this embodiment, the designer may operate based on the computer device, and the designer may input the attribute information of the design environment model into the computer device through any data input method. The computer device may determine available spatial information for the design environment model based on the attribute information for the design environment model. By way of example, the design environment model input by the designer is a three-room two-hall house, and the attribute information of the house may include the building area of the house, the house pattern of the house, the building type of the house, and the like. After the computer device obtains the attribute information of the house, the computer device can determine available space information of the house according to the attribute information of the house. The available space information of the house may include a size of the available space of the house, a shape of the available space, an electromechanical specification of the available space, a construction characteristic of the available space, a type of model that the available space can accommodate, and the like. For example, the type of model that a room can accommodate in a "bathroom" is the corresponding model of the bathroom, such as a toilet, shower stall, sink, etc.

S102, determining a plurality of functional area placement combinations according to the input functional area demand information and the available space information.

Each function area placement combination comprises a plurality of function areas associated with positions, and the function area demand information carries the number of the function areas required by a user and the types of the function areas.

Specifically, the functional area requirement information may characterize the functional requirements of the user on the design environment model. The functional requirements may include a practical functional requirement, a mental functional requirement, a technical functional requirement, other special functional requirements, an area ratio of each functional requirement in the whole design environment, a design style of the whole design environment, and the like. The functional area requirement information may be input to the computer device through a text input mode, or may be input to the computer device through a voice input mode, which is not limited in this embodiment. The function area requirement information input into the computer equipment carries the number of the function areas required by the user and the types of the function areas. The functional area refers to an area capable of meeting corresponding functional requirements, and optionally, the functional area can comprise at least one of a sleeping area, a sanitary area, an audio-visual area, a fitness area, a reading area, a finishing area and a coat and hat area.

The designer inputs the functional area requirement information required by the user for the design environment model into the computer equipment, and the computer equipment can acquire the number of the functional areas required by the user and the types of the functional areas from the functional area requirement information and determine a plurality of functional area placement combinations containing the requirements of the user by combining the available space information of the design environment model. Alternatively, the computer device may determine the size of the functional area required for each type according to the type of the functional area required for the user, and then determine a plurality of functional area placement combinations by combining the size of the available space of the design environment model and the number of the functional areas required for the user. Each functional area placement combination comprises each functional area required by a customer and the relative placement positions of the functional areas. It will be appreciated that there may be differences in the relative placement positions of the functional areas in the functional area placement combinations for different functional area placement combinations.

Exemplary, functional area demand information, such as a user entered into a computer device, is "I want to have rest, video, fitness, eating, learning, hygiene, storage functions in my house". The computer equipment can acquire that the number of the functional areas required by a user is 7 and the types of the 7 functional areas according to the input functional area requirement information, and then the computer equipment combines the available space information of the design environment model to put the 7 functional areas at different positions in the design environment model, so that a plurality of functional area arrangement combinations are formed.

S103, determining a target functional area placement combination with the largest comfort parameter from the plurality of functional area placement combinations according to a preset first screening strategy.

Specifically, the preset first screening strategy is used for screening the functional area placement combinations meeting basic comfort requirements. The target functional area placement combination with the largest comfort parameter can represent the target functional area placement combination to meet basic comfort requirements. The number of target functional area placement combinations with the largest comfort parameters determined by the computer equipment can be 1 or a plurality of target functional area placement combinations. When the computer equipment determines that the target functional area placement combination with the largest comfort parameter is a plurality of target functional area placement combinations, the computer equipment can randomly select or adopt a certain screening strategy to select one target functional area placement combination with the largest comfort parameter from the plurality of target functional area placement combinations with the largest comfort parameter as the target functional area placement combination which is finally output.

S104, outputting a design result according to the target functional area placement combination and filling models required by all the functional areas in the target functional area placement combination.

Specifically, the functional area corresponds to the filling model. One functional area may correspond to one filling model or may correspond to a plurality of filling models. For example, the filling model corresponding to the eating area can be a dining table and a dining chair. After the computer equipment determines the target functional area placement combination, the computer equipment determines filling models required by all functional areas in the target functional area placement combination from a preset model library, fills the filling models into the corresponding functional areas, and outputs design results after filling the filling models.

Fig. 2 is a flowchart of a data processing method according to another embodiment. This embodiment relates to an alternative process of how a computer device determines available spatial information for designing an environmental model. On the basis of the above embodiment, optionally, as shown in fig. 2, the step S101 includes:

s201, acquiring input attribute information of an existing model in the design environment model.

In particular, an existing model refers to a model that already exists in the design environment model. For example, where the design environment model is a house model, the existing model may be a window model, a door model, a pipe model, other existing models, etc. within the house model. The building types to which the existing model described above belongs may include public building types, commercial building types, residential building types, industrial building types, and the like. The room type of the existing model can be such as living room, dining room, kitchen, toilet, balcony, etc. The system types to which the existing model belongs may include base layer design, surface layer design, electromechanical devices, and the like. The geometric position information of the existing model may include relative position, absolute position, and posture information of the existing model. Where the relative position of an existing model refers to the position of one existing model relative to another existing model or the position of one existing model relative to the entire design environment model. For example, the relative position of existing model A may be that existing model A is to the left of another existing model B, or that existing model A is to the south of the entire design environment model. The absolute position of the existing model refers to the actual position coordinates of the existing model. The physical information of the existing model may include materials, colors, design styles, etc. of the existing model.

The input mode of the attribute information of the existing model in the design environment model may be a text input mode, a voice input mode, or other input modes, which is not limited in this implementation.

S202, determining available space information of the design environment model and environment characteristic information of the design environment model according to the attribute information of the existing model.

Specifically, the environmental characteristic information may be geographical location information, climate condition information, etc. where the design environmental model is located. For example, the geographic location information may be downtown, adjacent streets, north-south sitting, etc., and the climate condition information may be a southern humid climate, a northern dry climate, etc.

In this embodiment, the designer performs the operation based on the computer device, and the designer inputs the attribute information of the existing model in the design environment model into the computer device, so that the computer device can determine the available space information of the design environment model and the environment feature information of the design environment model according to the obtained attribute information of the existing model. Optionally, the computer device may obtain the available space information of the design environment model by calculating according to the corresponding calculation formula according to the area of the design environment model occupied by the existing model in the design environment model, the size of the existing model, the shape of the existing model, the position of the existing model, and the like, and then combining the space information of the design environment model itself. Optionally, the computer device may determine the environmental feature information where the design environment model is located according to the location of the existing model in the design environment model, the type of the existing model, and other attribute information. For example, according to the position of the entrance door and the position of the window in the design environment model, whether the geographic position information of the design environment model has good lighting can be obtained. And a floor heating or heating pipeline can be laid in the design environment model, so that the climate condition of the design environment model is approximately north dry climate.

In practical applications, the functional requirements of users may be relatively more, but the design environment model cannot bear the relatively more functional requirements of users due to the limited available space information of the design environment model. For this case, the computer device determines a plurality of functional region placement combinations in the design environment model using the following procedure as shown in fig. 3. Specifically, based on the above embodiment, as shown in fig. 3, the step S102 may include:

S301, determining the number of functional areas which can be placed in the design environment model according to the functional area demand information and the available space information.

Specifically, in an alternative embodiment, the process of determining, by the computer device, the number of functional areas that can be placed in the design environment model according to the functional area requirement information and the available space information may be: the computer equipment can determine the number of the functional areas required by the user and the types of the functional areas according to the functional area requirement information, then order all the functional areas based on the preset priority, calculate the accumulation area of the functional areas according to the area required by the functional areas corresponding to the priority according to the order of the priority from high to low, and determine the number of the functional areas which can be placed in the design environment model according to the accumulation area of the functional areas and the size of the available space information.

In another alternative embodiment, the process of determining, by the computer device, the number of functional areas that can be placed in the design environment model according to the functional area requirement information and the available space information may further be: determining a basic functional area and an alternative functional area according to the functional area demand information; judging whether the total occupied area of the basic functional area meets the size requirement of the available space information or not, and obtaining a judging result; and determining the number of functional areas which can be placed in the design environment model according to the judging result.

Specifically, the basic functional area is an area guaranteeing basic demands of users, such as a sleeping area and a sanitary area, and the alternative functional area is an area not requiring basic demands of users, such as a body-building area. When the computer equipment judges that the total occupied area of the basic functional areas is equal to the size requirement of the available space information, the computer equipment takes the number of the basic functional areas as the number of the functional areas which can be placed in the design environment model; when the computer equipment judges that the total occupied area of the basic functional areas is larger than the size requirement of the available space information, optionally, the computer equipment can screen one basic functional area from the basic functional areas at will, and judge again according to the screened result, so as to determine the number of functional areas which can be placed in the designed environment model; when the computer equipment judges that the total occupied area of the basic functional areas is smaller than the size requirement of the available space information, the computer equipment can select a corresponding number of alternative functional areas from the alternative functional areas according to the size requirement of the residual available space information, and the sum of the number of the basic functional areas and the number of the selected alternative functional areas is taken as the number of the functional areas which can be placed in the design environment model.

S302, determining a plurality of available functional areas according to the number of the functional areas and the priorities of the functional areas.

Specifically, the priority of each functional area may be preset in the computer device according to the requirement of the user, or may be obtained from other external devices, which is not limited in this embodiment. After the computer device determines the number of functional areas that can be placed in the design environment model, the computer device selects, from all functional areas, the functional areas with higher priorities that satisfy the number according to the priorities of the functional areas and the number of functional areas that can be placed in the design environment model determined in S301, thereby obtaining a plurality of available functional areas.

S303, determining the placement combination of the plurality of functional areas according to the plurality of available functional areas and the available space information.

Specifically, each functional area placement combination characterizes the placement positions of a plurality of available functional areas in the design environment model, and different functional area placement combinations refer to the different relative placement positions of the plurality of available functional areas in the design environment model.

For example, assume that a user needs to set 7 functional areas in a design environment model, and the 7 functional areas are a rest area, an audio-visual area, a fitness area, a dining area, a learning area, a sanitary area and a storage area. The computer equipment determines that the number of the functional areas which can be placed in the design environment model is 5 according to the available space information of the design environment model. Then, the computer device selects 5 functional areas with higher priority from the 7 functional areas (supposing that the selected 5 functional areas are a rest area, a dining area, a learning area, a sanitary area and a storage area respectively) based on the priorities of the functional areas, and then determines the specific placement positions of the 5 functional areas in the design environment model according to the available space information of the design environment model, so as to obtain a plurality of functional area placement combinations. Wherein, each functional area placement combination comprises the 5 functional areas selected above and also comprises the relative placement positions among the 5 functional areas. For example, fig. 4 shows any one of a plurality of functional area placement combinations. It can be understood that if the position of any one of the functional areas in the functional area placement combination shown in fig. 4 is adjusted, another functional area placement combination can be obtained.

As an alternative embodiment, S303 may be: and determining the placement combination of the plurality of functional areas according to the plurality of available functional areas, the available space information and the attribute information of the existing model.

Specifically, when an existing model exists in the design environment model, the computer device needs to determine a plurality of functional areas to put and combine according to a plurality of available functional areas, available space information and attribute information of the existing model in the design environment model. Taking a design environment model as an example of a bedroom in three rooms and two halls, a plurality of available functional areas determined by computer equipment are a sleeping area, an audio-visual area and a wardrobe area, and the existing model in the design environment model is a window, a door and a pipeline (an air conditioning hole or an inserting hole) of the bedroom. For this scenario, the attribute information of the existing model may include the location, size, style, etc. of the existing model. Thus, the computer equipment combines the attribute information of the existing models such as the position of the window in the bedroom, the position and the size of the door, the position of the pipeline and the like, and the available space information of the bedroom to determine the specific placement positions of the sleeping area, the video-audio area and the wardrobe area, so that a plurality of placement combinations of the sleeping area, the video-audio area and the wardrobe area are formed. Wherein, each functional area placement combination does not influence the normal use of the existing model.

As another alternative embodiment, S303 may be: and determining the placement combination of the plurality of functional areas according to the plurality of available functional areas, the available space information and the environment characteristic information of the design environment model.

In particular, the environmental characteristic information may include geographical location information, climate condition information, and the like. Taking a house with a design environment model as a three-room two-hall house as an example, for example, a plurality of available functional areas determined by computer equipment are a child house, an old man house and a reading area, and meanwhile, environmental characteristic information of the design environment model obtained by the computer equipment is an downtown area. After the computer equipment obtains available space information of a plurality of available functional areas, a design environment model and environment characteristic information of the design environment model, the computer equipment combines the environment characteristic information that the house is in the downtown area, places the old man house at a position far away from the downtown area, and then combines the available space information of the house and the placing position of the old man house, and carries out corresponding placement on other two functional areas (the child house and the reading area), thereby obtaining a plurality of placement combinations of the old man house, the child house and the reading area. The position of the old man house in each functional area placement combination is far away from the downtown area.

According to the data processing method provided by the embodiment, the computer equipment determines the number of the functional areas which can be placed in the design environment model according to the functional area demand information and the available space information, determines a plurality of available functional areas according to the number of the functional areas and the priority of each functional area, and then determines the placement combination of the plurality of functional areas according to the plurality of available functional areas and the available space information. When the arrangement combination of the plurality of functional areas is determined, the available space of the design environment model is combined, and the priority of each functional area required by a user is combined, so that the comfort matching degree of the final design result and the user requirement is higher, and the space utilization rate of the design environment model is improved.

Fig. 5 is a flowchart of a data processing method according to another embodiment. This embodiment relates to a specific process of how the computer device determines the target functional area placement combination with the largest comfort parameter. On the basis of the above embodiment, optionally, as shown in fig. 5, the step S103 may include:

s401, calculating the value of the comfort parameter corresponding to each function area placement combination.

Wherein, the value of the comfort parameter is equal to the sum of the weighting parameters corresponding to each functional area in the functional area placement combination; and the weighting parameter corresponding to the functional area is equal to the sum of the weights corresponding to the placement positions of the filling models in the functional area.

Specifically, each functional area corresponds to a corresponding filling model, and a plurality of placement positions can exist in the filling model in each functional area, and different placement positions have different weights. According to different placement positions of the filling models in the functional areas and the weight corresponding to each placement position, the computer equipment can obtain the weighting parameters corresponding to each functional area, and based on the sum of the weighting parameters of each functional area, the computer equipment can obtain the value of the comfort parameter corresponding to each functional area placement combination.

S402, determining the functional area placement combination with the largest value of the comfort parameter as the target functional area placement combination.

Specifically, the target functional area placement combination is a functional area placement combination meeting the basic comfort requirement of the user. Alternatively, the number of the functional area placement combinations with the largest comfort parameter value may be 1 or more. When the function area placement combination with the largest value of the comfort parameter is a plurality of function area placement combinations, optionally, the computer equipment can arbitrarily select one function area placement combination from the function area placement combinations with the largest values of the comfort parameters as the target function area placement combination. Of course, the target function region placement combination may be determined from the function region placement combinations with the largest values of the plurality of comfort parameters based on other algorithms, which is not limited in this embodiment.

Fig. 6 is a flow chart of a data processing method according to another embodiment, and fig. 7 is a flow chart of a data processing method according to another embodiment. The embodiment relates to a specific process how the computer device outputs the design result according to the target functional area placement combination and the filling model required by each functional area in the target functional area combination. In an alternative embodiment, based on the foregoing embodiment, as shown in fig. 6, the step S104 may include:

s501, determining various model filling combinations according to attribute information of filling models required by each functional area in the target functional area placing combinations.

Each model filling combination comprises a plurality of models which can be filled into the target functional area placement combination.

Specifically, the attribute information of the filling model may include information of a material, a manufacturer, a color, and the like of the filling model. Based on the attribute information of the filling models, the computer device may determine a plurality of filling models for the same class of filling models. For example, for the same class of filling model "beds", since "beds" have different manufacturers, colors, and materials, the computer device may determine the filling model for multiple "beds" for the same class of filling model "beds". Meanwhile, more than one filling model is required for each functional area, for example, the filling models required for the functional area "sleeping area" may include beds, bedside cabinets, bedside lamps, etc., and a plurality of filling models exist for each type of filling model. Thus, the computer equipment can determine various model filling combinations according to the attribute information of the filling models required by each functional area in the target functional area placement combination.

S502, screening from the plurality of model filling combinations according to a preset second screening strategy to obtain a target model filling combination, filling the target model filling combination into the target functional area placement combination, and outputting the design result.

Specifically, the preset second screening policy is other screening policies based on meeting the basic comfort requirement of the user, and may include price screening policies, style screening policies, and the like. Taking price screening strategy as an example, if the requirement of the user is price, the computer equipment screens a model filling combination with lower price from a plurality of model filling combinations, fills the model filling combination with lower price into a target functional area placement combination, and outputs a design result. Of course, when screening the target model filling combination, screening may be performed based on a plurality of second screening strategies, which is not limited in this embodiment.

As another alternative embodiment, based on the above embodiment, as shown in fig. 7, the step S104 may include:

s601, determining a first filling model required by each functional area in the target functional area placement combination according to each functional area in the target functional area placement combination and a preset mapping relation.

The mapping relation comprises the corresponding relation between different functional areas and each filling model.

Specifically, the preset mapping relation table may be preconfigured in the computer device, or may be obtained from other external devices. The mapping relation table may be in a table form, a corresponding connection line form, or an index form, which is not limited in this embodiment. After the target function area placement combination is obtained, the computer equipment determines a first filling model corresponding to each function area from a preset mapping relation table according to each function area in the target function area placement combination.

S602, filling the first filling models corresponding to the functional areas into the target functional area placement combination, and outputting the design result.

Specifically, after the computer device determines the first filling model required by each functional area in the target functional area placement combination, the computer device may fill the first filling model corresponding to each functional area into the target functional area placement combination, and output a design result. Optionally, the computer device may fill the first filling model corresponding to each functional area into the target functional area placement combination based on a selection operation of the designer. Alternatively, the selection operation may be a click operation, a sliding operation, or other types of selection operations, which is not limited in this embodiment.

Optionally, in one embodiment, in order to ensure the accuracy or applicability of the output design result (the applicability may be represented by the quality of the design result in the following embodiment), the computer device further performs at least one of the following operations after outputting the design result: determining whether the output design result is correct or not according to a preset design result quantification strategy, determining the degree of merit when the output design result is correct, and modifying the design result according to a preset design result modification strategy.

Wherein the design result quantization strategy and the design result modification strategy each comprise at least one of the following parameters: decoration national standard parameters, industry standard parameters, company standard parameters, production attributes of the filling model in the design environment model, processing attributes of the filling model in the design environment model, and installation attributes of the filling model in the design environment model.

Specifically, the national standard parameters of decoration include comfort parameters of design results. In this embodiment, the computer device may determine whether the output design result is correct according to a preset design result quantization policy. Optionally, the computer device may verify the correctness of the output design results based on the comfort level included in the finishing national standard parameters.

When the design result is determined to be correct, the computer equipment can also determine the quality degree of the output design result according to a preset design result quantization strategy. Optionally, the preset design result quantization policy may further include determining a quality degree of the output design result according to the input quantization parameter, that is, after the computer device outputs the design result, the designer may input a corresponding evaluation parameter into the computer device according to the design result, where the evaluation parameter may be a score, a star grade, or another parameter capable of ensuring the quality, and the computer device may determine the quality degree of the output design result according to the evaluation parameter input by the designer. Of course, the computer device can directly calculate the quality of the design result according to the comfort level of the design result.

On the other hand, the computer device may also modify the design result according to a preset design result modification policy. When the computer device determines that the output design result is incorrect, or receives a modification instruction of the designer, the computer device may modify the design result according to a preset design result modification policy. Optionally, the material of the filling model required by the functional area can be modified, the color of the filling model required by the functional area can be modified, and the placement position of the functional area in the target functional area placement combination can be modified. The specific content of the modification of the computer device is not limited in this embodiment, as long as the computer device can implement automatic modification of the design result according to the preset design result modification policy.

Optionally, the process of modifying the design result by the computer device according to the preset design result modification policy may be: the computer device may determine a design result modification policy according to the problems in the output design result, determine parameters to be modified according to the design result modification policy, and then modify the design result according to the parameters to be modified and the design result modification policy.

In one embodiment, to further meet the requirement of the user, optionally, the output design result in S104 may include: outputting the design result according to the scheme display requirement input by the user; wherein, the design result carries design budget information.

Specifically, the scheme display requirement input by the user can be one or more. For example, the user entered project presentation requirements may include design budget requirements, vendor information requirements for the filling model, environmental level information requirements for the filling model, and the like. Taking a scheme display requirement input by a user as a design budget requirement as an example, after the computer equipment obtains the scheme display requirement input by the user as the design budget requirement, the computer equipment carries the design budget information in a design result and outputs the design result carrying the budget information. Of course, when the solution display requirement input by the user is other requirements and the solution display requirement is plural, the computer device will carry the corresponding requirement information in the design result, and output the design result carrying the corresponding requirement information.

Fig. 8 is a flowchart of a data processing method according to another embodiment. As shown in fig. 8, the method includes:

s801, determining available space information of the design environment model according to the input attribute information of the design environment model.

Alternatively, the computer device may obtain the input attribute information of the existing model in the design environment model; and determining available space information of the design environment model and environment characteristic information of the design environment model according to the attribute information of the existing model. The description of this step may be specifically referred to the description of the above embodiment, and will not be repeated here.

S802, determining a plurality of functional area placement combinations according to the input functional area demand information and the available space information. Each function area placement combination comprises a plurality of function areas associated with positions, and the function area demand information carries the number of the function areas required by a user and the types of the function areas.

As a possible implementation manner, the computer device may determine the number of functional areas that can be placed in the design environment model according to the functional area requirement information and the available space information; determining a plurality of available functional areas according to the number of the functional areas and the priority of each functional area; and determining the placement combination of the plurality of functional areas according to the plurality of available functional areas and the available space information.

The description of this step may be specifically referred to the description of the above embodiment, and will not be repeated here.

S803, determining a target functional area placement combination with the largest comfort parameter from the plurality of functional area placement combinations according to a preset first screening strategy.

Optionally, the computer device may calculate a value of the comfort parameter corresponding to each of the functional zone placement combinations; and determining the functional area placement combination with the largest value of the comfort parameter as the target functional area placement combination.

S804, outputting a design result according to the target functional area placement combination and filling models required by all functional areas in the target functional area placement combination.

In an alternative embodiment, the computer device may determine a plurality of model filling combinations according to attribute information of filling models required by each function region in the target function region placement combination; and screening from the plurality of model filling combinations according to a preset second screening strategy to obtain a target model filling combination, filling the target model filling combination into the target functional area placement combination, and outputting the design result.

In another optional implementation manner, the computer device may determine a first filling model required by each functional area in the target functional area placement combination according to each functional area in the target functional area placement combination and a preset mapping relationship; and filling the first filling models corresponding to the functional areas into the target functional area placement combination, and outputting the design result. The mapping relation comprises the corresponding relation between different functional areas and each filling model.

Optionally, the computer device may display the requirement according to the scheme input by the user, and output the design result; wherein, the design result carries design budget information.

S805, determining whether the output design result is correct or not and determining the degree of quality when the output design result is correct according to a preset design result quantization strategy.

S806, when the design result needs to be modified, modifying the design result according to a preset design result modification strategy.

In the data processing method provided by the embodiment, in the whole design process of the scheme, the starting point of the scheme design is based on the functional requirements of the user, and the screening strategy for screening the target functional area placement combination is also based on whether the comfort requirements of the user can be met, so that the matching degree between the design result finally output by the computer equipment and the user requirements is higher. In addition, the whole design process is automatically designed by the computer equipment, so that the human participation process is reduced, the design efficiency of the designer is greatly improved, the influence of subjective consciousness of the designer on the design result is reduced, and the matching degree between the design result and the user requirement is further improved. After the computer equipment outputs the design result, whether the output design result is correct or not and the quality degree when the output design result is correct or not can be determined according to a preset design result quantization strategy, so that the matching degree between the output design result and the user requirement can be ensured, the quality degree of the output design result can be clarified, and the later optimization research and development can be facilitated; in addition, when the design result needs to be modified, the computer equipment can also automatically modify the design result according to a preset design result modification strategy, so that the repeated operation of a designer is simplified, the modification difficulty of the designer is reduced, and the working efficiency of the designer is greatly improved.

It should be understood that, although the steps in the flowcharts of fig. 1-8 are shown in order as indicated by the arrows, these steps are not necessarily performed in order as indicated by the arrows. The steps are not strictly limited to the order of execution unless explicitly recited herein, and the steps may be executed in other orders. Moreover, at least some of the steps in fig. 1-8 may include multiple sub-steps or stages that are not necessarily performed at the same time, but may be performed at different times, nor do the order in which the sub-steps or stages are performed necessarily occur sequentially, but may be performed alternately or alternately with at least a portion of the sub-steps or stages of other steps or steps.

Fig. 9 is a schematic structural diagram of a data processing apparatus according to an embodiment. As shown in fig. 9, the apparatus may include: a first determination module 11, a second determination module 12, a screening module 13 and a first processing module 14.

Specifically, the first determining module 11 is configured to determine available space information of the design environment model according to the input attribute information of the design environment model;

A second determining module 12, configured to determine a plurality of functional area placement combinations according to the input functional area requirement information and the available space information; each function area placement combination comprises a plurality of function areas associated with positions, and the function area demand information carries the number of the function areas and the types of the function areas required by a user;

the screening module 13 is configured to determine a target functional area placement combination with the largest comfort parameter from the multiple functional area placement combinations according to a preset first screening policy;

the first processing module 14 is configured to output a design result according to the target functional area placement combination and the filling model required by each functional area in the target functional area placement combination.

The data processing device provided in this embodiment may execute the above method embodiment, and its implementation principle and technical effects are similar, and will not be described herein.

Fig. 10 is a schematic structural diagram of a data processing apparatus according to another embodiment. On the basis of the above embodiment, optionally, as shown in fig. 10, the first determining module 11 includes: an acquisition unit 111, and a first determination unit 112.

Specifically, the obtaining unit 111 is configured to obtain the input attribute information of the existing model in the design environment model.

A first determining unit 112, configured to determine, according to attribute information of the existing model, available space information of the design environment model and environment feature information where the design environment model is located.

Fig. 11 is a schematic structural diagram of a data processing apparatus according to another embodiment. On the basis of the above embodiment, optionally, as shown in fig. 11, the second determining module 12 includes: a second determination unit 121, a third determination unit 122, and a fourth determination unit 123.

And a second determining unit 121, configured to determine the number of functional areas that can be placed in the design environment model according to the functional area requirement information and the available space information.

A third determining unit 122, configured to determine a plurality of available functional areas according to the number of functional areas and the priorities of the functional areas;

a fourth determining unit 123, configured to determine the placement combinations of the plurality of functional areas according to the plurality of available functional areas and the available space information.

In one embodiment, the second determining unit 121 is specifically configured to determine, according to the functional area requirement information, a basic functional area and an alternative functional area, determine whether a total occupied area of the basic functional area meets a size requirement of the available space information, obtain a determination result, and determine, according to the determination result, a number of functional areas that can be placed in the design environment model; the basic functional area is an area for guaranteeing basic requirements of users.

In one embodiment, the fourth determining unit 123 is specifically configured to determine the placement combinations of the plurality of functional areas according to the plurality of available functional areas, the available space information, and attribute information of the existing model.

In one embodiment, the fourth determining unit 123 is specifically configured to determine the placement combinations of the plurality of functional areas according to the plurality of available functional areas, the available space information, and the environmental feature information where the design environment model is located.

Fig. 12 is a schematic structural diagram of a data processing apparatus according to another embodiment. Based on the above embodiment, optionally, as shown in fig. 12, the screening module 13 may include: a calculation unit 131 and a fifth determination unit 132.

Specifically, the calculating unit 131 is configured to calculate a value of a comfort parameter corresponding to each functional area placement combination; wherein, the value of the comfort parameter is equal to the sum of the weighting parameters corresponding to each functional area in the functional area placement combination; and the weighting parameter corresponding to the functional area is equal to the sum of the weights corresponding to the placement positions of the filling models in the functional area.

A fifth determining unit 132, configured to determine a functional area placement combination with the largest value of the comfort parameter as the target functional area placement combination.

Fig. 13 is a schematic structural diagram of a data processing apparatus according to another embodiment. Optionally, as shown in fig. 13, the first processing module 14 includes: a sixth determination unit 141, a screening unit 142, and a first processing unit 143.

A sixth determining unit 141, configured to determine a plurality of model filling combinations according to attribute information of filling models required by each functional area in the target functional area placement combination; each model filling combination comprises a model capable of being filled into the target functional area placement combination.

And a screening unit 142, configured to screen the target model filling combinations from the plurality of model filling combinations according to a preset second screening policy.

The first processing unit 143 is configured to fill the target model filling combination obtained by the screening unit 142 into the target functional area placement combination, and output the design result.

Fig. 14 is a schematic structural diagram of a data processing apparatus according to another embodiment. Optionally, as shown in fig. 14, the first processing module 14 includes: a seventh determination unit 144 and a second processing unit 145.

Specifically, the seventh determining unit 144 is configured to determine, according to each functional area in the target functional area placement combination and a preset mapping relationship, a first filling model required by each functional area in the target functional area placement combination; the mapping relation comprises the corresponding relation between different functional areas and each filling model.

And the second processing unit 145 is configured to fill the first filling models corresponding to the functional areas into the target functional area placement combination, and output the design result.

Fig. 15 is a schematic structural diagram of a data processing apparatus according to another embodiment. Optionally, as shown in fig. 15, the data processing apparatus further includes: a second processing module 15.

Specifically, the second processing module 15 is configured to determine whether the output design result is correct according to a preset design result quantization policy, determine the degree of merit when the output design result is correct, and modify the design result according to a preset design result modification policy.

In one embodiment, the first processing unit 143 or the second processing unit 145 is specifically configured to output the design result according to the requirement of the scheme display input by the user. Wherein, the design result carries design budget information.

For specific limitations of the data processing apparatus, reference may be made to the above limitations of the data processing method, and no further description is given here. Each of the modules in the above-described data processing apparatus may be implemented in whole or in part by software, hardware, and combinations thereof. The above modules may be embedded in hardware or may be independent of a processor in the computer device, or may be stored in software in a memory in the computer device, so that the processor may call and execute operations corresponding to the above modules.

In one embodiment, a computer device is provided, which may be a terminal, and the internal structure of which may be as shown in fig. 1 a. The computer device includes a processor, a memory, a network interface, a display screen, and an input device connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device includes a non-volatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program is executed by a processor to implement a data processing method. The display screen of the computer equipment can be a liquid crystal display screen or an electronic ink display screen, and the input device of the computer equipment can be a touch layer covered on the display screen, can also be keys, a track ball or a touch pad arranged on the shell of the computer equipment, and can also be an external keyboard, a touch pad or a mouse and the like.

It will be appreciated by persons skilled in the art that the architecture shown in FIG. 1a is merely a block diagram of some of the architecture relevant to the present inventive arrangements and is not limiting as to the computer device to which the present inventive arrangements may be implemented, a particular computer device may include more or fewer components than shown, or may combine some of the components, or have a different arrangement of components.

In one embodiment, a computer device is provided comprising a memory storing a computer program and a processor implementing the following steps when executing the computer program:

In one embodiment, a computer readable storage medium is provided having a computer program stored thereon, which when executed by a processor, performs the steps of:

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims

1. A method of data processing, comprising:

determining available space information of the design environment model according to the input attribute information of the design environment model; the attribute information of the design environment model comprises self attribute information of the design environment model and attribute information of an existing model in the design environment model;

calculating the value of the comfort parameter corresponding to each functional area placement combination; wherein, the value of the comfort parameter is equal to the sum of the weighting parameters corresponding to each functional area in the functional area placement combination; the weighting parameters corresponding to the functional areas are equal to the sum of the weights corresponding to the placement positions of the filling models in the functional areas; different placement positions have different weights;

Determining the functional area placement combination with the largest value of the comfort parameter as a target functional area placement combination; when the function area placement combination with the largest value of the comfort parameter is a plurality of function area placement combinations, determining the target function area placement combination from the function area placement combination with the largest value of the plurality of comfort parameters; the value of the comfort parameter maximally characterizes the comfort requirement of the user;

2. The method of claim 1, wherein determining available spatial information of the design environment model based on the entered attribute information of the design environment model comprises:

3. The method of claim 2, wherein determining a plurality of functional area placement combinations based on the entered functional area demand information and the available space information comprises:

4. The method of claim 3, wherein determining the number of functional areas that can be placed within the design environment model based on the functional area requirement information and the available space information comprises:

5. The method of claim 3, wherein said determining said plurality of functional area placement combinations from said plurality of available functional areas and said available spatial information comprises:

6. The method of claim 3, wherein said determining said plurality of functional area placement combinations from said plurality of available functional areas and said available spatial information comprises:

7. The method according to any one of claims 1 to 6, wherein outputting the design result according to the target functional area placement combination and the filling model required for each functional area in the target functional area placement combination includes:

8. The method according to any one of claims 1-6, wherein outputting the design result according to the target functional area placement combination and the filling model required for each functional area in the target functional area combination includes:

9. The method of any of claims 1-6, wherein after the outputting the design result, the method further comprises at least one of:

10. The method of any of claims 1-6, wherein outputting the design result comprises:

11. The method of any one of claims 1-6, wherein the functional region comprises: at least one of sleeping area, sanitary area, video-audio area, body-building area, reading area, arrangement area and coat-hat area.

12. A data processing apparatus, comprising:

the first determining module is used for determining available space information of the design environment model according to the input attribute information of the design environment model; the attribute information of the design environment model comprises self attribute information of the design environment model and attribute information of an existing model in the design environment model;

the screening module is used for calculating the value of the comfort parameter corresponding to each functional area placement combination; wherein, the value of the comfort parameter is equal to the sum of the weighting parameters corresponding to each functional area in the functional area placement combination; the weighting parameters corresponding to the functional areas are equal to the sum of the weights corresponding to the placement positions of the filling models in the functional areas; different placement positions have different weights; determining the functional area placement combination with the largest value of the comfort parameter as a target functional area placement combination; when the function area placement combination with the largest value of the comfort parameter is a plurality of function area placement combinations, determining the target function area placement combination from the function area placement combination with the largest value of the plurality of comfort parameters; the value of the comfort parameter maximally characterizes the comfort requirement of the user;

and the processing module is used for outputting a design result according to the target functional area placement combination and the filling model required by each functional area in the target functional area placement combination.

13. A computer device comprising a memory and a processor, the memory storing a computer program, characterized in that the processor implements the steps of the method of any of claims 1-11 when the computer program is executed.

14. A computer readable storage medium, on which a computer program is stored, characterized in that the computer program, when being executed by a processor, implements the steps of the method according to any of claims 1-11.