KR102431890B1 - Method of providing a three dimensional sample view based on modeling data of differential quality rendered on a server, and apparatus therefor - Google Patents

Abstract

The present invention relates to a method and apparatus for providing a three-dimensional sample view, in which a low-quality image generated from a user device is overlayed, based on high-quality modeling data rendered on a server through a network from the user device consisting of a processor, a memory, a display module, and a communication module. More specifically, the method includes: a step of allowing the user device to transmit sample view configuration including sample object configuration, user image configuration, and customized area configuration through a network; a step of allowing the user device to receive modeling data rendered on the server from the server through the network according to the sample view configuration; and a step of allowing the user device to display the three-dimensional sample view by overlaying the user image to the modeling data. The method and apparatus can efficiently provide the three-dimensional sample view based on modeling data of differential quality rendered on the server.

Description

Method and apparatus for providing a three-dimensional sample view based on modeling data of differential quality rendered on the server

The present invention relates to a method and apparatus for providing a three-dimensional sample view, and more particularly, to a method and apparatus for providing a three-dimensional sample view based on modeling data of differential quality rendered on a server.

When the image generated through the image design work on the computer is actually applied to various products, it is difficult to give the same feeling to the real thing to check the actual feeling of the products to which the image is applied through a display device.

In the case of an actual product, there is a difference in the image that the user feels depending on the movement of the product by the external environment such as the texture of the product and the light source, and simply providing the user with the image created through computer design is synthesized with the product image. , there was a problem in that the user-generated image and product image were not accepted as one overall design, and the immersion was not felt because the difference in effects according to the external environment was different.

In addition, it is often impossible to generate a high-quality image in a general user device in view of the general specifications of the user device, and even if it is possible to generate a high-quality image, a considerable amount of time is required. Therefore, displaying a 3D sample object using a relatively low-quality image generated by the user device cannot give the user a sense of immersion, so it is necessary to solve the problem.

Registered patent KR 10-2091217 B1 (2020.03.13)

Registered Patent KR 10-2144336 B1 (2020.08.07)

Registered patent KR 10-1817145 B1 (2018.01.04)

Based on the above discussion, hereinafter, the present invention intends to provide a 3D sample view based on modeling data of differential quality rendered on a server.

The technical problems to be achieved in the present invention are not limited to the above technical problems, and other technical problems not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the following description.

In a user device comprising a processor, a memory, a display module and a communication module, which is an aspect of the present invention for solving the above-mentioned problems, based on high-quality modeling data rendered on a server through a network, low-quality In the method of providing a three-dimensional sample view overlaid with a user image, in the user device, sample view configuration including sample object setting, user image setting, and custom area setting is performed over a network. transmitting to the server via; receiving, by the user device, server-rendered modeling data according to the sample view setting from the server through a network; and displaying, by the user device, a three-dimensional sample view by overlaying the user image on the modeling data.

Furthermore, the transmitting of the sample view setting to the server may include: receiving, by the user device, the sample object setting for providing the 3D sample view from the user; displaying, by the user device, a development image based on the sample object setting to the user; receiving, by the user device, the user image setting based on the user image setting for overlaying the user image on the modeling data from the user; and transmitting, by the user device, a sample view setting including the input user image setting and the sample object setting to the server through a network.

Furthermore, the sample view setting may include setting the sample object, setting a custom region for a custom region in which the user image can be overlaid on the unfolded image, and setting the position and size of the user image on the custom region. It may be characterized in that it includes a user image setting.

Furthermore, the modeling data, corresponding to the sample object setting and the user image setting, in the server, the shape, structure, color, sample detail and effect (effect) is characterized in that it comprises three-dimensional modeling data pre-rendered. can do.

Furthermore, the 3D modeling data includes at least a portion of the shape corresponding to the setting of the user-defined area, and is set so that at least a portion including a specific effect among the effects is not included. ; and cover layer modeling data that corresponds to the sample object setting and is set to include at least a part of the effect including the specific effect, and is set to a color to which a preset transparency is applied to the three-dimensional modeling data can be characterized as

Furthermore, in the base layer modeling data, an area corresponding to the user-defined area may be processed as a blank area.

Furthermore, the displaying of the 3D sample view may include, in the user device, overlaying the user image on the customized area of the base layer modeling data based on the 3D modeling data, and overlaying the user image It may be characterized in that the base layer modeling data is displayed to the user.

Furthermore, the displaying of the three-dimensional sample view may include, by the user device, overlaying the cover layer modeling data so as to cover both the user image and the base layer modeling data, and displaying the overlaid to the user.

Furthermore, the three-dimensional modeling data further includes background modeling data set to correspond to a sample object of the base layer modeling data, and the displaying of the three-dimensional sample view may include, in the user device, the background modeling data. It may be characterized in that it is displayed to the user by underlaying the base layer modeling data.

Furthermore, the method may further include providing a sample object list including at least one third sample object different from the sample object setting to the user by applying the user image setting.

In another aspect of the present invention for solving the above problems, a user device that provides a three-dimensional sample view overlaid with a low-quality user image based on high-quality modeling data rendered on a server through a network , processor; a memory coupled to the processor; a display module controlled through the processor; and a communication module controlled through the processor, wherein the processor transmits a sample view configuration of the user image to the server through a network, and receives the sample view configuration from the server through the network. It may be characterized in that it receives the server-rendered modeling data according to the above, and overlays the user image on the modeling data to display a three-dimensional sample view.

According to an embodiment of the present invention, it is possible to provide a method and apparatus for efficiently providing a 3D sample view based on modeling data of differential quality rendered on a server.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included as part of the detailed description for helping the understanding of the present invention, provide embodiments of the present invention, and together with the detailed description, explain the technical spirit of the present invention.
1 is a block diagram of a system for providing a 3D sample view based on modeling data of differential quality rendered on a server according to the present invention.
2 is a reference diagram of a method for providing a 3D sample view based on modeling data of differential quality rendered on a server according to the present invention.
3 is a reference diagram for explaining a process of transmitting a sample view setting to a server on a user device according to the present invention.
4 is an exemplary diagram of a method for providing a 3D sample view based on modeling data of differential quality rendered on a server according to the present invention.
5, 6, 7A, 7B, 7C, 7D and 7E are reference diagrams for explaining a method of providing a 3D sample view based on modeling data of differential quality rendered on a server according to the present invention .

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. Like reference numerals in each figure indicate like elements. In the embodiments described below, the present invention is not limited to the description of the embodiments described below, and it is apparent that various modifications may be made without departing from the technical gist of the present invention. And in describing the embodiments, descriptions of technical contents that are widely known in the technical field to which the present invention pertains and are not directly related to the technical gist of the present invention will be omitted.

Meanwhile, in the accompanying drawings, the same components are represented by the same reference numerals.

And in the accompanying drawings, some components may be exaggerated, omitted, or schematically shown. This is to clearly explain the gist of the present invention by omitting unnecessary descriptions not related to the gist of the present invention.

1 is a block diagram of a system for providing a 3D sample view based on modeling data of differential quality rendered on a server according to the present invention. The three-dimensional sample view system according to the present invention may include a user device 100 , a network 200 , and a server 300 .

The user device 100 may include a processor 110 , a memory 120 , a display module 130 , and a communication module 140 , and high-quality modeling rendered on the server 300 through the network 200 . Based on the data, it is possible to provide a three-dimensional sample view overlaid with a low-quality user image generated by the user device.

In general, the user device generally lacks the specifications for generating a high-quality graphic image, and even though it is possible to generate a high-quality graphic image, it takes a considerable amount of time for rendering to generate a high-quality graphic image. Even if you create a , waiting for it to be rendered is not practically easy.

Therefore, in the present invention, after rendering high-quality modeling data in advance on the server, a relatively low-quality user image generated by the user is overlaid, the modeling data and the user image can be seen in a unified sense, and external effects are applied uniformly By doing so, it is possible to provide users with an immersive 3D sample view.

The processor 110 controls the memory 120 , the display module 130 , and the communication module 140 , and controls processes and data performed in the user device. In the present invention, all processes performed by the user device may be controlled through the processor.

The memory 120 is connected to the processor and stores data processed by the processor.

The display module 130 is controlled through the processor, and may display graphic data processed through the processor to the user.

The communication module 140 is controlled through the processor, and can transmit various data processed through the processor to an external device connected indirectly through a direct connection or a network.

The user device may control the communication module in the processor to transmit a sample view configuration including the user image setting and the sample object setting to the server through the network.

The user image setting refers to the setting for the user image to be overlaid on the sample object, such as the image uploaded by the user for overlaying the sample, the size of the image, the position the image occupies on the custom area, the ratio, and the rotation setting. .

The sample object setting relates to a basic sample (eg, t-shirt, sign, cup, banner, etc.) on which the user image is overlaid, and the user device or server may receive the user to select a sample on which the user image is to be overlaid. and is defined by the related settings.

The sample view setting includes a user image setting and a sample object setting, and may further include information about the size, shape, location, etc. of a custom region that is an overlayable region on a sample in which the user image is selected or a developed image of the sample.

The user device controls a separate interface module (not shown, for example, a keyboard, mouse, touch pen, etc.) with a processor to receive a sample object setting input from the user to provide a 3D sample view.

The user device controls, through the processor, to retrieve the deployment image based on the sample object setting from the memory and display it to the user. Here, the unfolded image is an image displayed on a plane in which a user image is overlaid on a three-dimensional sample object, and the displayed image shape may be variously set according to the sample object setting. In addition, the development image is a two-dimensional plane representation of a three-dimensional shape of a sample selected according to a sample object setting, and may be controlled to be displayed so that the customized area is located in the center on the display module.

For example, when a user image is overlaid on a plane, such as a T-shirt, a banner, or a sign, at least one of the front side or the back side of the area where the user image is to be overlaid on the unfolded image may be provided to the user as an image.

As another example, in the case of a paper cup or a paper box, in order for the user image to be overlaid on a plane, the development view of the paper cup, the development view of the paper box, etc. may be provided as an image to the user, can

The user device controls a separate interface module with a processor to receive a user image setting based on a custom area setting for overlaying a user image on modeling data related to a sample from a user based on the development image. That is, the user device displays, on the development image related to the sample, a customized area having a shape provided by default related to the sample or additionally set by the user, and the size, position, ratio, and rotation of the user in the displayed customized area User image settings applied by customizing (rotation) are input.

The user device includes a user image setting and a sample object setting input from the user, and provides a sample view setting that is basically provided in the user device according to the sample object or includes a custom area setting set by the user to the network 200 is transmitted to the server 300 through

The user device may control the communication module through the processor to receive the modeling data rendered on the server corresponding to the sample view setting transmitted from the server through the network.

In the present invention, modeling data is not only two-dimensional modeling data corresponding to sample object setting and user image setting, but also shape, structure, color, sample detail and effect ( effect) may include pre-rendered 3D modeling data.

In the present invention, the sample detail is the basic modeling data based on the shape, structure, and color of the sample. It is defined as information modified on the server. That is, in the present invention, rather than simply displaying the modeling data of the sample to the user, by additionally setting the detail of the sample on the server to perform rendering and provide, a more immersive and realistic 3D sample view can be provided to the user. have. The reason that the sample detail is set in the modeling data in the present invention is that the size of the modeling data, the ratio of the customized area, etc. vary depending on the sample view setting. It is difficult to create. Therefore, basic modeling data exists with respect to the shape, structure, and color of the sample, and by applying various changes to the shape, structure, color, etc. according to the sample view setting, data management can be performed efficiently.

The effect is not only basic effects such as external and internal light effects and shadows, but also external effects such as reflection or reflection due to external light (e.g., fluorescent lamp, incandescent bulb), etc. An external effect is applied to the sample based on the detail, and the effect on the modeling data is an effect applied based on the sample detail (for example, shadows due to crumpled parts, the shape of fluorescent lamps are distorted in recessed parts, etc.) is included

In the present invention, the three-dimensional modeling data, specifically, may be set to at least one of base layer modeling data, cover layer modeling data, and background modeling data.

The base layer modeling data is modeling data on which a user image is overlaid, and on the 3D modeling data in which shape, structure, color, sample detail, and effect are pre-rendered, at least including a specific effect among pre-rendered effects. It is set not to include a part, and is defined as 3D modeling data including at least a part corresponding to the custom area setting among pre-rendered shapes. Accordingly, the base layer modeling data includes at least a portion of the shape corresponding to the user-defined area setting, and may further include at least one of structure, color, and sample detail, but at least a portion of the pre-rendered effect (ie, a specific effect). ) is set not to be included.

That is, as basic modeling data for representing a three-dimensional sample view by overlaying a user image on a custom area of three-dimensional modeling data, the user image is sample detail on the base layer modeling data that is modeling data from which at least a part of the effect is excluded. By being overlaid based on 3D modeling data including

Further, to this end, in the base layer modeling data, an area corresponding to the user-defined area may be processed as a blank area. Even if the user image is overlaid by removing the color or processing the blank area in the present invention to be transparent. It is possible to prevent color errors that may occur due to overlapping images (for example, multiple images are viewed as overlapping on one area due to overlapping images with high transparency). Details are set to be included.

The cover layer modeling data is set to include at least a part including a specific effect among the effects set not to be included on the base layer modeling data, and the user image is set to cover all of the overlaid base layer modeling data modeling data. At least one of the shape, structure, and sample detail corresponding to the sample object setting is processed so that there is no color on the 3D modeling data in relation to color, or the transparency of the color is preset to a predetermined level or higher. , transparent or transparent, so that the effect and sample detail are uniformly applied to the user image and the base layer modeling data overlaid with the user image.

The background modeling data is set to correspond to a sample object of the base layer modeling data, and the base layer modeling data of the present invention is displayed at a predetermined angle with the virtual ground for a three-dimensional sample view. Accordingly, the background modeling data may be underlayed on the base layer modeling data to correspond to the angle formed by the base layer modeling data with the virtual ground, thereby improving the sense of reality of the 3D sample view.

The user device may display the 3D sample view to the user by overlaying the user image on the modeling data on the received modeling data through the processor.

The user device may overlay the user image on a blank area of the base layer modeling data based on the 3D modeling data, and display the base layer modeling data on which the user image is overlaid to the user. That is, the user device checks the settings for the shape, structure, sample detail, and effect of the sample on the 3D modeling data, and the user image based on the shape, structure, and sample detail of the sample on the customization area of the base layer modeling data. The user image is overlaid and displayed according to the setting.

In other words, according to the shape, structure, and sample detail modified on the server from which the color has been removed from the modeling data, the user image to which the position, size, rotation, etc. according to the user image setting is applied is overlaid on the set customization area and displayed to the user. can

The user device may additionally overlay the cover layer modeling data to cover both the user image and the base layer modeling data and display it to the user, and display the background modeling data to the user by underlaying the base layer modeling data. have.

A detailed description related to the sample display on the user device will be described later in more detail with reference to FIGS. 4 to 6 to be described later.

In addition, the user device may additionally provide a sample object list including at least one third sample object different from the sample object setting to the user by applying the user image setting. That is, if a 3D sample view is presented by overlaying a user image on a paper cup to the user, the user image may be overlaid on a paper cup different from the paper cup, a paper bag, a paper box, etc. according to the user image setting and additionally provided to the user. .

2 is a reference diagram for explaining a method of providing a 3D sample view overlaid with a user image in a user device according to an embodiment of the present invention. The user device controls the memory, the display module, and the communication module through the processor, and provides a 3D sample view overlaid with the low-quality user image generated in the user device using the high-quality modeling data rendered on the server through the network. can do

The user device controls the communication module through the processor to transmit a sample view configuration including sample object setting, user image setting, and custom area setting to the server through the network (S201).

That is, the user device provides a sample view setting including a sample object setting input from the user, a custom region setting provided or set on the user device according to the sample object setting, and a user image setting generated based on the custom region setting to the server. by sending a request to the server for settings regarding the three-dimensional sample to be overlaid by the user image.

The user device receives the server-rendered modeling data according to the sample view setting through the network from the server (S203).

The modeling data is modeling data corresponding to a sample according to the sample view setting, and may be set as base layer modeling data, cover layer modeling data, and background modeling data.

According to an embodiment of the present invention, modeling data may be set and received as base layer modeling data, cover layer modeling data, and background modeling data individually generated on the server, but as another embodiment of the present invention, modeling data is Base layer modeling data received on the user device, including settings and data on the shape, structure, sample detail, and effect of the sample, and based on the settings and data on the shape, structure, sample detail, and effect of the sample on the user device; Cover layer modeling data and background modeling data can also be set.

The user device overlays the user image on the modeling data to display a three-dimensional sample view (S205).

Based on the received 3D modeling data, the user device provides a 3D sample view to the user using the base layer modeling data, the cover layer modeling data, and the background modeling data generated from the server, or 3D modeling data on the user device After generating base layer modeling data, cover layer modeling data, and background modeling data using settings and data on the shape, structure, sample detail, and effect of the base sample, a 3D sample view can be provided to the user.

The user device may provide a simple 3D sample to the user by overlaying the user image on the customized area of the base layer modeling data. This provision allows the 3D sample view to be displayed without placing a heavy load on the user device because effect processing or background data is omitted.

The user device applies the cover layer modeling data so as to cover both the custom image and the base layer modeling data to the sample overlaid with the user image on the custom area of the base layer modeling data, so that the user image and the user image are overlaid on the base layer It is possible to uniformly apply sample details and effects to modeling data. The effect of the cover layer modeling data is an effect based on the sample detail, and can provide a 3D sample view with a sense of unity to the user.

In the present invention, by not only showing the high-quality base layer modeling data rendered for a long time in the server using a high-performance processor together with the low-quality user image generated in the user device to the user, but also applying the high-quality effect of the cover layer modeling data to the whole, With high-quality image recognition according to the high-quality base layer modeling data and the cover layer modeling data, the user has the effect that even a low-quality user image has an optical illusion of high quality. That is, by simply applying the effect according to the cover layer modeling data, not only the sense of unity of the user image and the base layer modeling data, but also the optical illusion of image quality is provided to the user, and the user provides a more immersive 3D sample can receive

Additionally, the user device may provide additional immersion and sense of unity by displaying the background modeling data set to correspond to the sample object of the base layer modeling data to the user by underlaying the base layer modeling data. The background modeling data is set to correspond to a sample object of the base layer modeling data, and the base layer modeling data of the present invention is displayed at a predetermined angle with the virtual ground for a three-dimensional sample view. Accordingly, the background modeling data may be underlayed on the base layer modeling data to correspond to the angle formed by the base layer modeling data with the virtual ground, thereby improving the sense of reality of the 3D sample view.

3 is a flowchart illustrating a method of transmitting a sample view setting from a user device to a server according to an embodiment of the present invention.

The user device receives a sample object setting input from the user (S301). The user device may provide the user with a list of various objects preset in order to provide a 3D sample view, and receive the sample object from the user through a separate interface module (eg, keyboard, mouse, touch pen, etc.) can be entered.

The user device provides a deployment image based on the sample object setting to the user (S303). The unfolded image may be displayed in various ways according to the sample object setting, and the unfolded image is displayed centered on the customizable area where the user image can be overlaid. According to the display setting of the display module, it is preferable to adjust the coordinates of the center of the customized area to provide it to the user, and to set the basic shape of the user image to be located in the center of the customized area.

The user device, based on the deployment image, receives a user image setting (S305). That is, the user device displays the user-defined area on the developed image, displays the basic shape of the user image, and then confirms the user image setting according to the user's additional operation.

The user device transmits the sample view setting to the server through the network (S307). The sample view setting is for requesting modeling data rendered on the server, the user image setting and sample object setting are input from the user, and the customization area is provided by default in the user device for the sample object setting or is separately selected by the user will be included through However, the user image is not included in the sample view setting, because in the present invention, a process of overlaying the user image on the modeling data in the user device is performed.

4 is a reference diagram of a method for providing a 3D sample view based on modeling data of differential quality rendered on a server according to the present invention.

The user device overlays the user image 401 on the customized area of the base layer modeling data 403 based on the sample view setting based on the user image 401 . The base layer modeling data 403 includes at least a portion of a shape to include a customized area for the user image 401 to be overlaid. However, it is not excluded that it may be set as a part of the shape including the custom area. The base layer modeling data is set so that at least a part of the rendered effect is not included, and FIG. 4 exemplifies a case in which all of the rendered effects are not included in the base layer modeling data. Accordingly, the user image is also overlaid by reflecting the sample detail on the user-defined area according to the sample detail related to the base layer modeling data.

However, by simply overlaying the user image 401 on the base layer modeling data 403, it is difficult to give the user a sense of unity and immersion. Accordingly, the user device applies the cover layer modeling data 405 to cover both the user image 401 and the base layer modeling data 405 . The cover layer modeling data includes a part of the shape corresponding to the setting in the sample object (that is, the front of the signboard), and is set to include all of the effects set not to be included in the base layer modeling data (ie, the glitter effect). Assume Accordingly, a common sample detail is applied to the user image 401 and the base layer modeling data 403 , and all effects belonging to the cover layer modeling data may be applied. The cover layer modeling data 405 is transparent or semi-transparent as described above, and transparency is preset in the 3D sample view without affecting the color or sample detail of the user image and the base layer modeling data. applied to improve.

Furthermore, the user device applies the background modeling data to correspond to the setting of the sample object of the base layer modeling data because the base layer modeling data is set to the angle θ formed with the virtual ground, and the three-dimensional sample view 407 ) is completed.

5 to 7E are reference diagrams for explaining a method of providing a 3D sample view based on modeling data of differential quality rendered on a server according to the present invention.

When an embodiment of the present invention is described with reference to FIG. 5 , the user device provides a UI 501 for receiving a selection of a sample object to the user, and receives a sample for setting a 3D sample view from the user. For example, when the user sets a sample object called 'T-shirt', the user device displays a developed image and a set rectangular custom area in relation to the 'T-shirt', and displays the user image on the custom area (503). The user inputs various settings such as size, position, rotation, and font of the user image on the user-customized area ( 505 ). The user device transmits the user settings based on the user's input to the server through the network, receives modeling data for this, and overlays the user image on the modeling data to provide the user with a three-dimensional sample view ( 507 ).

Referring to FIG. 6 , the user device provides a UI 601 for receiving a selection of a sample object to the user to set a sample from the user. As another example, when the user sets a sample object called 'paper cup', the user device provides a fan-shaped development image set in relation to 'paper cup' to the user. That is, the T-shirt of FIG. 5 provides a fan-shaped development image corresponding to the paper cup in FIG. 6 in a different form from that of providing the front or back image of the T-shirt. A customized area is displayed on the fan-shaped development image, and the user image is displayed on the customized area (603). When a user inputs a sample view setting and receives modeling data corresponding thereto, a 3D sample view is provided to the user by overlaying the user image on the modeling data ( 605 ). Referring to the final three-dimensional sample view of FIG. 6 , it can be seen that a part of the user image is deformed according to the shape of the joint part of the paper cup, and the shadow effect is applied only to a part of the user image. In other words, a user image is overlaid based on the shape, structure, and sample detail of the base layer modeling data (ie, paper cup), and a cover layer in which a shadow effect is applied only to a part of the joint of the paper cup according to the sample detail of the base layer modeling data. modeling data is applied. Furthermore, it can be confirmed that the background modeling data (eg, the support plate of the upper part, etc.) is applied according to the virtual ground of the paper cup.

7A to 7E are reference diagrams for more specifically explaining the application of the cover layer modeling data. Referring to FIG. 7A, the user image (ie, the preview) is the base layer modeling data (ie, the sign) in the angle setting. It is not only overlaid based on the base, but also the cover layer modeling data with shadow effect applied to only a part of the sign is applied, so it can be seen that there is a difference in the contrast of the user image. Referring to FIG. 7B , the user image (ie, the preview) is overlaid on the base layer modeling data (ie, the wall plate), and the light effect (eg, fluorescent lamp image) applied to the entire base layer modeling data is applied to the entire sign. It can be seen that the effect of reflection on the glass material is also applied to the sign. Referring to FIG. 7C , the user image is deformed according to the sample detail (ie, curvature) of the base layer modeling data (ie, wrapping paper), and the reflection effect of the wrapping paper is applied as a whole according to the cover layer modeling data, so that the user image It can be seen that there is a difference in the contrast of each part. 7D also shows that the 'light source' (cover layer modeling data) is applied only to a part of the 'container' (base layer modeling data), so that the contrast of the 'A' part of 'Miri' is set differently, giving the user a sense of immersion. can FIG. 7E shows a user image (eg, Miga) according to the base layer modeling data (eg, a banner) is overlaid with sample detail applied and curved according to the cover layer modeling data (eg, a light source) By applying the effect, it can be confirmed that the partial contrast of the user image (ie, Miri) is different.

Therefore, according to an embodiment of the present invention, even if the user image is rendered with a relatively low quality in the user device, the server displays the image rendered in high quality by overlaying and uniformly applying the external effect, so that the user image causes an optical illusion of high quality like an image rendered in the server, and has the effect of reducing the waiting time for the user through relatively low-quality, short-time rendering on the user device.

The embodiments of the present invention published in the present specification and drawings are merely provided for specific examples to easily explain the technical content of the present invention and help the understanding of the present invention, and are not intended to limit the scope of the present invention. It will be apparent to those of ordinary skill in the art to which the present invention pertains that other modifications based on the technical spirit of the present invention can be implemented in addition to the embodiments disclosed herein.

Claims (11)

A three-dimensional sample view overlaid with a low-quality user image generated in the user device based on high-quality modeling data rendered on the server through the network in the user device consisting of the processor, memory, display module and communication module In the method of providing,
transmitting, in the user device, a sample view configuration including sample object setting, user image setting, and custom area setting to the server through a network;
The user device receives 3D modeling data in which shape, structure, color, sample detail and effect are pre-rendered from the server, corresponding to the sample object setting and the user image setting through the network from the server to do; and
and displaying, by the user device, a three-dimensional sample view by overlaying the user image on the modeling data,
The three-dimensional modeling data is,
base layer modeling data set to include at least a portion of the shape corresponding to the setting of the customized region and not include at least a portion including a specific effect among the effects;
At least a portion of a shape corresponding to the sample object setting, including at least one of a structure, and a sample detail, is set to include at least a portion of the effect including the specific effect, and the transparency preset in the three-dimensional modeling data is Cover layer modeling data set to the applied color; and
It is set as background modeling data set to correspond to the sample object of the base layer modeling data,
Displaying the three-dimensional sample view comprises:
The user device overlays the user image on the customized area from which a specific effect based on the base layer modeling data is excluded based on the 3D modeling data, and the user image is overlaid on the base layer modeling data, The cover layer modeling data is overlaid so that the specific effect covers both the user image and the base layer modeling data, and the background modeling data is underlay based on an angle formed with the virtual ground associated with the base layer modeling data. ) characterized in that it is displayed to the user,
How to provide a three-dimensional sample view.
The method of claim 1,
The step of sending the sample view setting to the server comprises:
receiving, by the user device, the sample object setting for providing the 3D sample view from the user;
displaying, by the user device, a development image based on the sample object setting to the user;
receiving, by the user device, the user image setting based on the user image setting for overlaying the user image on the modeling data from the user based on the development image; and
and transmitting, by the user device, a sample view setting including the input user image setting and the sample object setting to the server through a network,
How to provide a three-dimensional sample view.
3. The method of claim 2,
The sample view setting is
It characterized in that it comprises the sample object setting, the user image setting for the position and size of the user image on the customized region, and the user image setting on the customized region on the development image, the user image can be overlaid on the custom region setting. doing,
How to provide a three-dimensional sample view.
delete delete The method of claim 1,
The base layer modeling data is,
An area corresponding to the user-defined area is treated as a blank area,
How to provide a three-dimensional sample view.
delete delete delete The method of claim 1,
The method further comprising the step of providing a sample object list composed of at least one third sample object different from the sample object setting to the user by applying the user image setting,
How to provide a three-dimensional sample view.
A user device that provides a three-dimensional sample view overlaid with a low-quality user image based on high-quality modeling data rendered on a server through a network,
processor;
a memory coupled to the processor;
a display module controlled through the processor; and
It includes a communication module controlled through the processor,
The processor is
A sample view configuration of the user image is transmitted to the server through a network, and a shape, structure, color, Receive modeling data in which sample details and effects are pre-rendered, and overlay the user image on the modeling data to display a three-dimensional sample view,
The three-dimensional modeling data is,
base layer modeling data set to include at least a portion of the shape corresponding to the setting of the customized region and not include at least a portion including a specific effect among the effects;
At least a portion of a shape corresponding to the sample object setting, including at least one of a structure, and a sample detail, is set to include at least a portion of the effect including the specific effect, and the transparency preset in the 3D modeling data is Cover layer modeling data set to the applied color; and
It is set as background modeling data set to correspond to the sample object of the base layer modeling data,
The three-dimensional sample view is
Based on the three-dimensional modeling data, the user image is overlaid on the user-customized area in which a specific effect based on the base layer modeling data is excluded, and the user image and the user image are overlaid on the base layer modeling data over which the user image is overlaid. Overlaying the base layer modeling data so that all the specific effects cover the base layer modeling data, and underlaying the background modeling data based on an angle formed with the virtual ground associated with the base layer modeling data. doing,
user device.

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