CN116776451A - Color mixing method and device for environment design - Google Patents
Color mixing method and device for environment design Download PDFInfo
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Abstract
The invention relates to the technical field of intelligent environment design, and particularly discloses a color mixing method and device for environment design, wherein the method comprises the steps of pushing a reference model to a design end; receiving selection information and an adjustment instruction of a design end, and determining an arrangement model; creating an environment parameter chain according to a construction area map, and updating the arrangement model according to the environment parameter chain; and inquiring an actual scene of the reference model, determining error characteristics according to the actual scene and the reference model, and correcting the updated arrangement model according to the error characteristics. According to the invention, the reference model is selected through a big data technology, and a designer carries out modified design in the reference model, so that the time for modeling the framework is saved; when the design is completed, an environment parameter chain is established according to the address uploaded by the demand end, and the designed product is updated, so that a designer can intuitively see products in different environments, and then make corresponding adjustment, and the working efficiency of the designer in a limited time is greatly improved.
Description
Technical Field
The invention relates to the technical field of intelligent environment design, in particular to a color mixing method and device for environment design.
Background
The environment design has very close relation with life, production, work and leisure of people. Along with the improvement of living standard and living level, the requirements of people on various environmental artistic quality are higher and higher, and the requirements on the work of environmental designers are also provided.
In the existing environment design process, a designer combines own theoretical knowledge, design ideas and design experience, different design products can be made according to different requirements, the requirements on the designer are high, the design productivity of the top designer is limited, most of design tasks are finished by vast common design workers, the common design workers hardly spend excessive time on a small design task due to time cost, in this case, the probability that the design products are inconsistent with the actual conditions is high, and in particular, in a specific environment, negative effects such as a foggy weather and the like can be generated on the design products.
How to reduce the working difficulty of the design workers, so that the design workers can better design products in a limited time, and the technical problem to be solved by the technical scheme of the invention is solved.
Disclosure of Invention
The present invention is directed to a method and apparatus for environmental design to solve the above-mentioned problems.
In order to achieve the above purpose, the present invention provides the following technical solutions:
a method of tinting for environmental design, the method comprising:
receiving a construction area map and construction cost sent by a demand end, and pushing a reference model to a design end according to the construction area map and the construction cost;
receiving selection information and an adjustment instruction of a design end, and determining an arrangement model; the placement model includes component locations and component parameters; the component parameters comprise component materials and component colors;
creating an environment parameter chain according to a construction area map, and updating the arrangement model according to the environment parameter chain; introducing a time factor based on the component materials in the updating process of the arrangement model;
and inquiring an actual scene of the reference model, determining error characteristics according to the actual scene and the reference model, and correcting the updated arrangement model according to the error characteristics.
As a further scheme of the invention: the step of receiving the construction area map and the construction cost sent by the demand end and pushing the reference model to the design end according to the construction area map and the construction cost comprises the following steps:
receiving a construction area range sent by a demand end, and sending grids with preset precision to the demand end;
receiving height information at each grid node fed back by a demand end, and building a construction area map according to the height information and the construction area range;
traversing a construction area map, extracting map features of the construction area map, and matching a reference model in a preset reference model library according to the map features;
and receiving construction cost sent by the demand end, screening the matched reference model according to the construction cost, and pushing the screened reference model to the design end.
As a further scheme of the invention: the step of receiving the selection information and the adjustment instruction of the design end and determining the arrangement model comprises the following steps:
receiving selection information sent by a design end, and selecting a target model from the reference model;
receiving an adjusting instruction uploaded by a design end, and adjusting the position and parameters of each component in the target model based on the adjusting instruction to obtain an arrangement model;
and updating the component cost library at fixed time, determining the cost information of the arrangement model according to the component cost library, and displaying the cost information in real time.
As a further scheme of the invention: the step of creating an environment parameter chain according to the construction area map and updating the arrangement model according to the environment parameter chain comprises the following steps:
inquiring the address of the construction area range, and acquiring weather parameters in a preset number of preset periods according to the address; the preset period is one year in lunar calendar;
comparing weather parameters of different sub-periods in the same period, calculating to obtain a difference value array, classifying the weather parameters according to the difference value array, and determining duration of various weather parameters according to classification results; the sub-period is a day;
counting various weather parameters and duration time thereof in each period, and calculating average parameters and average time thereof;
inputting the mean value parameters into a trained layer conversion model, and outputting an adjustment layer; the adjusting layer is used for representing the adjusting degree of different colors;
determining the proportion of the adjustment layers according to the average time length, and counting the adjustment layers according to the proportion to obtain an environment parameter chain;
the placement model is updated based on the chain of environmental parameters.
As a further scheme of the invention: the step of inquiring the actual scene of the reference model, determining error characteristics according to the actual scene and the reference model, and correcting the updated arrangement model according to the error characteristics comprises the following steps:
inquiring a reference model corresponding to the arrangement model, reading an environment parameter chain, adjusting the reference model, and determining a theoretical scene;
reading an actual scene corresponding to a reference model, comparing the actual scene with the theoretical scene, and determining error characteristics; the error characteristic is a matrix;
inputting the error characteristics into a preset numerical normalization model to obtain correction rate;
and correcting the updated arrangement model according to the correction rate.
As a further scheme of the invention: the step of reading the actual scene corresponding to the reference model, comparing the actual scene with the theoretical scene, and determining the error feature comprises the following steps:
reading an actual scene corresponding to the reference model;
reading a grid with preset precision, and determining sampling points in an actual scene and a theoretical scene based on the grid;
acquiring color values at sampling points, and inputting the color values into a preset error calculation function to obtain errors at all the sampling points;
counting errors at all sampling points based on the grids to obtain error characteristics;
wherein the error calculation function is:
wherein D is an error,and->Dividing into color values at two sampling points, < >>Parameters preset for the staff.
The technical scheme of the invention also provides a color mixing device for environmental design, which comprises:
the standard model pushing module is used for receiving the construction area map and the construction cost sent by the demand end and pushing a standard model to the design end according to the construction area map and the construction cost;
the arrangement model generation module is used for receiving the selection information and the adjustment instruction of the design end and determining an arrangement model; the placement model includes component locations and component parameters; the component parameters comprise component materials and component colors;
the arrangement model updating module is used for creating an environment parameter chain according to the construction area map and updating the arrangement model according to the environment parameter chain; introducing a time factor based on the component materials in the updating process of the arrangement model;
the arrangement model correction module is used for inquiring the actual scene of the reference model, determining error characteristics according to the actual scene and the reference model, and correcting the updated arrangement model according to the error characteristics.
As a further scheme of the invention: the reference model pushing module comprises:
the range receiving unit is used for receiving the construction area range sent by the demand end and sending grids with preset precision to the demand end;
the map building unit is used for receiving the height information of each grid node fed back by the demand end and building a building area map according to the height information and the building area range;
the model matching unit is used for traversing the map of the construction area, extracting the map features of the map of the construction area and matching a reference model in a preset reference model library according to the map features;
and the model screening unit is used for receiving the construction cost sent by the demand end, screening the matched reference model according to the construction cost, and pushing the screened reference model to the design end.
As a further scheme of the invention: the arrangement model generation module includes:
the target selecting unit is used for receiving the selecting information sent by the design end and selecting a target model from the reference models;
the component adjusting unit is used for receiving the adjusting instruction uploaded by the design end, and adjusting the position and the parameters of each component in the target model based on the adjusting instruction to obtain the arrangement model;
and the cost display unit is used for updating the component cost library at fixed time, determining the cost information of the arrangement model according to the component cost library and displaying the cost information in real time.
As a further scheme of the invention: the arrangement model updating module comprises:
the weather parameter query unit is used for querying addresses of the construction area range and acquiring weather parameters in a preset number of preset periods according to the addresses; the preset period is one year in lunar calendar;
the classification unit is used for comparing weather parameters of different sub-periods in the same period, calculating to obtain a difference value array, classifying the weather parameters according to the difference value array, and determining duration of various weather parameters according to classification results; the sub-period is a day;
the average feature calculation unit is used for counting various weather parameters and duration time of the weather parameters in each period and calculating average parameters and average time of the average parameters;
the layer adjusting output unit is used for inputting the mean value parameters into the trained layer conversion model and outputting an adjusting layer; the adjusting layer is used for representing the adjusting degree of different colors;
the layer statistics unit is used for determining the proportion of the adjustment layer according to the average time length, and carrying out statistics on the adjustment layer according to the proportion to obtain an environment parameter chain;
and the updating execution unit is used for updating the arrangement model based on the environment parameter chain.
Compared with the prior art, the invention has the beneficial effects that: according to the invention, the reference model is selected through a big data technology, and a designer carries out modified design in the reference model, so that the time for modeling the framework is saved; when the design is completed, an environment parameter chain is established according to the address uploaded by the demand end, and the designed product is updated, so that a designer can intuitively see products in different environments, and then make corresponding adjustment, and the working efficiency of the designer in a limited time is greatly improved.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the following description will briefly introduce the drawings that are needed in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are only some embodiments of the present invention.
FIG. 1 is a flow diagram of a toning method for environmental design.
FIG. 2 is a first sub-flowchart block diagram of a toning method for environmental design.
FIG. 3 is a second sub-flowchart block diagram of a toning method for environmental design.
FIG. 4 is a third sub-flowchart block diagram of a toning method for environmental design.
FIG. 5 is a third sub-flowchart block diagram of a toning method for environmental design.
Detailed Description
In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.
FIG. 1 is a block flow diagram of a method for tinting an environmental design, in an embodiment of the present invention, a method for tinting an environmental design, the method comprising:
step S100: receiving a construction area map and construction cost sent by a demand end, and pushing a reference model to a design end according to the construction area map and the construction cost;
the demand end refers to a party with design demand, the demand end uploads a construction area map and construction cost, and the design end carries out environmental art design in the construction area map according to the construction cost; in the design process, an execution subject of the method queries a reference model which is already established in advance according to a construction area map and construction cost; the reference model is historical built data and corresponds to an actual building.
Step S200: receiving selection information and an adjustment instruction of a design end, and determining an arrangement model; the placement model includes component locations and component parameters; the component parameters comprise component materials and component colors;
the number of the reference models pushed at one time is not unique, the design end needs to upload selection information to determine a reference model conforming to the design concept, and then, some adjustment is carried out on the basis of the reference model, wherein the adjustment content comprises the types, parameters and positions of components; of these, the most important is the color of the component, and the component color matching process is the core content of the environmental art design.
Step S300: creating an environment parameter chain according to a construction area map, and updating the arrangement model according to the environment parameter chain; introducing a time factor based on the component materials in the updating process of the arrangement model;
acquiring environmental parameters according to the geographic position of the construction area map, and creating an environmental parameter chain according to the environmental parameters at different moments; and updating the generated arrangement model through the created environment parameter chain, so that the display state of the arrangement model under different environment parameters can be obtained.
The updating process of the arrangement model needs to introduce a time factor for representing the time change condition of each component in the arrangement model, especially the color change condition.
Step S400: inquiring an actual scene of a reference model, determining error characteristics according to the actual scene and the reference model, and correcting the updated arrangement model according to the error characteristics;
the arrangement model is generated on the basis of the reference model, the reference model is queried, the reference model is analyzed by adopting the same calculation flow, the theoretical state of the reference model under different environmental parameters can be determined, the theoretical state and the actual scene are compared due to the existence of the actual scene (the necessary condition for determining the reference model) corresponding to the reference model, the error rate of the theoretical calculation process can be determined, and the arrangement model can be corrected according to the error rate.
Fig. 2 is a first sub-flowchart of a color matching method for environmental design, where the step of receiving a construction area map and construction cost sent by a demand end and pushing a reference model to a design end according to the construction area map and the construction cost includes:
step S101: receiving a construction area range sent by a demand end, and sending grids with preset precision to the demand end;
the method comprises the steps that a demand end firstly sends a construction area range, the construction area range is two-dimensional data, an execution main body of the method can determine a grid according to the construction area range, the unit size in the grid is a preset value, and the smaller the size is, the higher the accuracy is.
Step S102: receiving height information at each grid node fed back by a demand end, and building a construction area map according to the height information and the construction area range;
and the grid is sent to a demand end, the demand end uploads the height information of each grid node, and then an execution subject of the method establishes a construction area map according to the height information and a construction area range, wherein the construction area map is three-dimensional data, and the height information is introduced on the basis of the range.
Step S103: traversing a construction area map, extracting map features of the construction area map, and matching a reference model in a preset reference model library according to the map features;
traversing the map of the construction area, extracting map features based on a preset feature extraction algorithm, and matching the map features with a reference model; in the process of generating the reference model library, the same feature extraction algorithm is required to extract the map features of the reference model in advance, and establish the map feature item serving as the index.
Step S104: receiving construction cost sent by a demand end, screening the matched reference model according to the construction cost, and pushing the screened reference model to a design end;
the number of the matched reference models is large, the construction cost of different reference models is different, the construction cost sent by the demand end is received, and the matched reference models can be further screened.
FIG. 3 is a second sub-flowchart of a toning method for environmental design, wherein the steps of receiving selection information and adjustment instructions of a design end and determining an arrangement model include:
step S201: receiving selection information sent by a design end, and selecting a target model from the reference model;
step S202: receiving an adjusting instruction uploaded by a design end, and adjusting the position and parameters of each component in the target model based on the adjusting instruction to obtain an arrangement model;
step S203: and updating the component cost library at fixed time, determining the cost information of the arrangement model according to the component cost library, and displaying the cost information in real time.
The determining process of the layout model is an interactive process, and a designer at the design end uploads the selection information and the adjustment instruction in real time to adjust the selected target model.
In the process, the cost information of the arrangement model is determined in real time according to the component cost which changes regularly, and the cost information is displayed, so that the design process of a designer is more targeted.
FIG. 4 is a third sub-flowchart of a toning method for environmental design, the steps of creating an environmental parameter chain from a construction area map, updating the placement model from the environmental parameter chain include:
step S301: inquiring the address of the construction area range, and acquiring weather parameters in a preset number of preset periods according to the address; the preset period is one year in lunar calendar;
inquiring the address of the construction area range, and inquiring the annual historical weather parameters according to the address; the year is limited, and lunar calendar is adopted.
Step S302: comparing weather parameters of different sub-periods in the same period, calculating to obtain a difference value array, classifying the weather parameters according to the difference value array, and determining duration of various weather parameters according to classification results; the sub-period is a day;
the weather parameters of one year consist of the weather parameters of each day, the weather parameters of each day are compared, and the weather parameters can be classified according to the comparison result; the weather parameters are obtained by adopting indexes in the existing weather forecast, including temperature, humidity, wind direction, wind power and the like; after classification is completed, it can be calculated how many days each type of weather parameter includes, called duration.
Step S303: counting various weather parameters and duration time thereof in each period, and calculating average parameters and average time thereof;
and analyzing weather parameters of each year in turn, counting the days of each type of weather parameters in each year, calculating a mean number of days (mean time), and calculating the mean parameters according to the weather parameters.
Step S304: inputting the mean value parameters into a trained layer conversion model, and outputting an adjustment layer; the adjusting layer is used for representing the adjusting degree of different colors;
the average value parameter and the average value duration reflect the average condition of weather parameters in the address of the construction area range, and the average value parameter is input into a preset layer conversion model to establish an adjusting layer, wherein the adjusting layer is used for adjusting the tone of the arrangement model.
Step S305: determining the proportion of the adjustment layers according to the average time length, and counting the adjustment layers according to the proportion to obtain an environment parameter chain;
each type of weather parameter corresponds to one adjustment layer, and the adjustment layers are statistically arranged according to the average time length, so that an environment parameter chain can be obtained; for the statistical arrangement process, specific explanation is needed, the proportion is determined by the mean time length, and on the basis, the adjustment chart layer group within 30s can be obtained by distributing 30s according to the proportion by combining the default display time length preset by staff, such as 30s, and the adjustment chart layer group is called an environment parameter chain.
Step S306: updating the placement model based on the chain of environmental parameters;
and updating the arrangement model by means of the existing image processing technology to obtain the states of the arrangement model under different weather parameters.
It should be noted that, regarding the time factor, the adjustment layer may be modified by the time factor, or an influence layer group that changes with time may be established according to the time factor, where the influence layer in the time influence layer group is used to characterize the color influence degree on different materials.
FIG. 5 is a third sub-flowchart of a toning method for environmental design, the querying an actual scene of a reference model, determining error features from the actual scene and the reference model, and modifying an updated placement model based on the error features, the steps comprising:
step S401: inquiring a reference model corresponding to the arrangement model, reading an environment parameter chain, adjusting the reference model, and determining a theoretical scene;
and reading the reference model, and updating the reference model by adopting the same updating mode to obtain a theoretical scene.
Step S402: reading an actual scene corresponding to a reference model, comparing the actual scene with the theoretical scene, and determining error characteristics; the error characteristic is a matrix;
and acquiring an actual scene and a theoretical scene, and determining an error condition according to the comparison result.
Step S403: inputting the error characteristics into a preset numerical normalization model to obtain correction rate;
the numerical value normalization model is used for converting the matrix into a numerical value, and an existing matrix processing mode is adopted; for example, the matrix is converted into a determinant, and the values of the determinant are adjusted.
Step S404: correcting the updated arrangement model according to the correction rate;
and (3) carrying out integral adjustment on the updated arrangement model according to the correction rate.
Further, the step of reading the actual scene corresponding to the reference model, comparing the actual scene with the theoretical scene, and determining the error feature includes:
reading an actual scene corresponding to the reference model;
reading a grid with preset precision, and determining sampling points in an actual scene and a theoretical scene based on the grid;
acquiring color values at sampling points, and inputting the color values into a preset error calculation function to obtain errors at all the sampling points;
counting errors at all sampling points based on the grids to obtain error characteristics;
the error calculation process is limited by the above, firstly, a grid is read, the grid is used for establishing a map of a construction area, and nodes of the grid are used as sampling points; then, reading an actual scene corresponding to the reference model, comparing the actual scene with a theoretical scene based on sampling points, and calculating errors at all sampling points; finally, according to the sampling point, the error is counted, and a matrix called error characteristic can be obtained.
Wherein the error calculation function is:
;
wherein D is an error,and->Dividing into color values at two sampling points, < >>And parameters preset for staff are used for adjusting the error calculation process.
It should be noted that the error calculation function is a piecewise function, any of which can be independently used as the calculation function, the purpose of the piecewise function is to improve the smoothness of the error result, which is differentCorresponding results are different, +.>Autonomous setting is required by a worker in advance according to a sample calculation process.
In a preferred embodiment of the present invention, there is provided a toning apparatus for environmental design, the apparatus comprising:
the standard model pushing module is used for receiving the construction area map and the construction cost sent by the demand end and pushing a standard model to the design end according to the construction area map and the construction cost;
the arrangement model generation module is used for receiving the selection information and the adjustment instruction of the design end and determining an arrangement model; the placement model includes component locations and component parameters; the component parameters comprise component materials and component colors;
the arrangement model updating module is used for creating an environment parameter chain according to the construction area map and updating the arrangement model according to the environment parameter chain; introducing a time factor based on the component materials in the updating process of the arrangement model;
the arrangement model correction module is used for inquiring the actual scene of the reference model, determining error characteristics according to the actual scene and the reference model, and correcting the updated arrangement model according to the error characteristics.
Wherein, the benchmark model pushing module includes:
the range receiving unit is used for receiving the construction area range sent by the demand end and sending grids with preset precision to the demand end;
the map building unit is used for receiving the height information of each grid node fed back by the demand end and building a building area map according to the height information and the building area range;
the model matching unit is used for traversing the map of the construction area, extracting the map features of the map of the construction area and matching a reference model in a preset reference model library according to the map features;
and the model screening unit is used for receiving the construction cost sent by the demand end, screening the matched reference model according to the construction cost, and pushing the screened reference model to the design end.
Further, the arrangement model generation module includes:
the target selecting unit is used for receiving the selecting information sent by the design end and selecting a target model from the reference models;
the component adjusting unit is used for receiving the adjusting instruction uploaded by the design end, and adjusting the position and the parameters of each component in the target model based on the adjusting instruction to obtain the arrangement model;
and the cost display unit is used for updating the component cost library at fixed time, determining the cost information of the arrangement model according to the component cost library and displaying the cost information in real time.
Specifically, the arrangement model updating module includes:
the weather parameter query unit is used for querying addresses of the construction area range and acquiring weather parameters in a preset number of preset periods according to the addresses; the preset period is one year in lunar calendar;
the classification unit is used for comparing weather parameters of different sub-periods in the same period, calculating to obtain a difference value array, classifying the weather parameters according to the difference value array, and determining duration of various weather parameters according to classification results; the sub-period is a day;
the average feature calculation unit is used for counting various weather parameters and duration time of the weather parameters in each period and calculating average parameters and average time of the average parameters;
the layer adjusting output unit is used for inputting the mean value parameters into the trained layer conversion model and outputting an adjusting layer; the adjusting layer is used for representing the adjusting degree of different colors;
the layer statistics unit is used for determining the proportion of the adjustment layer according to the average time length, and carrying out statistics on the adjustment layer according to the proportion to obtain an environment parameter chain;
and the updating execution unit is used for updating the arrangement model based on the environment parameter chain.
The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.
Claims (10)
1. A method of tinting an environment design, the method comprising:
receiving a construction area map and construction cost sent by a demand end, and pushing a reference model to a design end according to the construction area map and the construction cost;
receiving selection information and an adjustment instruction of a design end, and determining an arrangement model; the placement model includes component locations and component parameters; the component parameters comprise component materials and component colors;
creating an environment parameter chain according to a construction area map, and updating the arrangement model according to the environment parameter chain; introducing a time factor based on the component materials in the updating process of the arrangement model;
and inquiring an actual scene of the reference model, determining error characteristics according to the actual scene and the reference model, and correcting the updated arrangement model according to the error characteristics.
2. The method for environment design according to claim 1, wherein the step of receiving the construction area map and the construction cost sent by the demand end and pushing the reference model to the design end according to the construction area map and the construction cost comprises:
receiving a construction area range sent by a demand end, and sending grids with preset precision to the demand end;
receiving height information at each grid node fed back by a demand end, and building a construction area map according to the height information and the construction area range;
traversing a construction area map, extracting map features of the construction area map, and matching a reference model in a preset reference model library according to the map features;
and receiving construction cost sent by the demand end, screening the matched reference model according to the construction cost, and pushing the screened reference model to the design end.
3. The method for environmental design toning according to claim 1, wherein the step of receiving the selection information and the adjustment instruction of the design end and determining the placement model includes:
receiving selection information sent by a design end, and selecting a target model from the reference model;
receiving an adjusting instruction uploaded by a design end, and adjusting the position and parameters of each component in the target model based on the adjusting instruction to obtain an arrangement model;
and updating the component cost library at fixed time, determining the cost information of the arrangement model according to the component cost library, and displaying the cost information in real time.
4. The method for toning environmental design of claim 2, wherein the step of creating an environmental parameter chain from a construction area map, and updating the layout model from the environmental parameter chain comprises:
inquiring the address of the construction area range, and acquiring weather parameters in a preset number of preset periods according to the address; the preset period is one year in lunar calendar;
comparing weather parameters of different sub-periods in the same period, calculating to obtain a difference value array, classifying the weather parameters according to the difference value array, and determining duration of various weather parameters according to classification results; the sub-period is a day;
counting various weather parameters and duration time thereof in each period, and calculating average parameters and average time thereof;
inputting the mean value parameters into a trained layer conversion model, and outputting an adjustment layer; the adjusting layer is used for representing the adjusting degree of different colors;
determining the proportion of the adjustment layers according to the average time length, and counting the adjustment layers according to the proportion to obtain an environment parameter chain;
the placement model is updated based on the chain of environmental parameters.
5. The method of claim 1, wherein the step of querying the actual scene of the reference model, determining error features from the actual scene and the reference model, and correcting the updated placement model based on the error features comprises:
inquiring a reference model corresponding to the arrangement model, reading an environment parameter chain, adjusting the reference model, and determining a theoretical scene;
reading an actual scene corresponding to a reference model, comparing the actual scene with the theoretical scene, and determining error characteristics; the error characteristic is a matrix;
inputting the error characteristics into a preset numerical normalization model to obtain correction rate;
and correcting the updated arrangement model according to the correction rate.
6. The method for environmental design of claim 5, wherein the step of reading an actual scene corresponding to the reference model, comparing the actual scene with the theoretical scene, and determining an error feature comprises:
reading an actual scene corresponding to the reference model;
reading a grid with preset precision, and determining sampling points in an actual scene and a theoretical scene based on the grid;
acquiring color values at sampling points, and inputting the color values into a preset error calculation function to obtain errors at all the sampling points;
counting errors at all sampling points based on the grids to obtain error characteristics;
wherein the error calculation function is:
;
wherein D is an error,and->Respectively two sampling pointsColor value of place->Is a preset parameter.
7. A tinting device for environmental design, the device comprising:
the standard model pushing module is used for receiving the construction area map and the construction cost sent by the demand end and pushing a standard model to the design end according to the construction area map and the construction cost;
the arrangement model generation module is used for receiving the selection information and the adjustment instruction of the design end and determining an arrangement model; the placement model includes component locations and component parameters; the component parameters comprise component materials and component colors;
the arrangement model updating module is used for creating an environment parameter chain according to the construction area map and updating the arrangement model according to the environment parameter chain; introducing a time factor based on the component materials in the updating process of the arrangement model;
the arrangement model correction module is used for inquiring the actual scene of the reference model, determining error characteristics according to the actual scene and the reference model, and correcting the updated arrangement model according to the error characteristics.
8. The apparatus for environmental design of claim 7, wherein the reference model pushing module comprises:
the range receiving unit is used for receiving the construction area range sent by the demand end and sending grids with preset precision to the demand end;
the map building unit is used for receiving the height information of each grid node fed back by the demand end and building a building area map according to the height information and the building area range;
the model matching unit is used for traversing the map of the construction area, extracting the map features of the map of the construction area and matching a reference model in a preset reference model library according to the map features;
and the model screening unit is used for receiving the construction cost sent by the demand end, screening the matched reference model according to the construction cost, and pushing the screened reference model to the design end.
9. The apparatus for environmental design of claim 7, wherein the placement model generation module comprises:
the target selecting unit is used for receiving the selecting information sent by the design end and selecting a target model from the reference models;
the component adjusting unit is used for receiving the adjusting instruction uploaded by the design end, and adjusting the position and the parameters of each component in the target model based on the adjusting instruction to obtain the arrangement model;
and the cost display unit is used for updating the component cost library at fixed time, determining the cost information of the arrangement model according to the component cost library and displaying the cost information in real time.
10. The apparatus for environmental design of claim 8, wherein the placement model updating module comprises:
the weather parameter query unit is used for querying addresses of the construction area range and acquiring weather parameters in a preset number of preset periods according to the addresses; the preset period is one year in lunar calendar;
the classification unit is used for comparing weather parameters of different sub-periods in the same period, calculating to obtain a difference value array, classifying the weather parameters according to the difference value array, and determining duration of various weather parameters according to classification results; the sub-period is a day;
the average feature calculation unit is used for counting various weather parameters and duration time of the weather parameters in each period and calculating average parameters and average time of the average parameters;
the layer adjusting output unit is used for inputting the mean value parameters into the trained layer conversion model and outputting an adjusting layer; the adjusting layer is used for representing the adjusting degree of different colors;
the layer statistics unit is used for determining the proportion of the adjustment layer according to the average time length, and carrying out statistics on the adjustment layer according to the proportion to obtain an environment parameter chain;
and the updating execution unit is used for updating the arrangement model based on the environment parameter chain.
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