KR20150123062A - Method And System for Forming Image Space Using Multiple Projectors - Google Patents

Abstract

The present invention relates to a method and system for realizing an image space using multiple projectors, which can easily realize a high resolution image by using two or more projectors, and can provide an image of a high quality having very little difference between adjacent images even though a screen is configured by projecting each image with the projectors. Also, the present invention does not require a separate screen device which occupies interior space in a building but uses the interior space itself such as a wall surface or the floor of the building as screen, thereby having no limits to an installation place, and not changing an existing interior structure but projecting an image without the distortion accordingly.

Description

TECHNICAL FIELD The present invention relates to a method and system for implementing a video space using a multi-projector,

The present invention relates to a method and system for implementing an image space using a multi-projector, and more particularly, to a system and method for realizing an image space using multiple projectors, And more particularly, to a method and system for realizing an image space using a multi-projector capable of projecting images of a plurality of projectors.

Generally, in a performance hall, various event venues, and exhibition halls, a device capable of displaying a large image in order to focus visitors' attention and effectively guide event topics and various information is often required. A liquid crystal display (LCD) And a video device using a diode (LED).

However, in the case of a video device using a liquid crystal display (LCD), cost increases exponentially when a liquid crystal display panel is enlarged to a predetermined size or more, and also technically, It was not possible to satisfy the large screen required in a performance hall or a venue.

Therefore, although a multi-vision system in which a plurality of liquid crystal display devices are two-dimensionally arranged and implemented by a single image device is used, a uniform interval is necessarily required between the unit liquid crystal display devices in terms of structure There has been a problem that one image is cut off and displayed. In addition, although the above-mentioned multivision can theoretically enlarge the image size by using a plurality of liquid crystal display devices, the limitation of the enlargement is obvious due to the economical and operational limitations.

On the other hand, an image display device using a light emitting diode (LED) is an LED display panel, which is an image display device widely used as a large image display device since the LED bulb is modularized and arranged. However, since the plurality of LED bulbs themselves constitute a pixel unit, the distance between the LED bulbs is not distinguished due to diffusion due to the diffusion of light. However, in the case of a dark screen, . Therefore, it is necessary to arrange the LED bulbs to be as close as possible to each other. However, in such a case, there is a problem in that the competitiveness is lost in terms of cost.

In the case of the exhibition hall or the event hall, visitors often take commemorative photographs. In the case of photographing with the LED signboard as the background, the image displayed on the LED signboard is not photographed as it is, The arrangement state is revealed as it is, and there is a problem that photography is hardly possible in the background.

In addition, even if LED light bulb of 7.5mm pitch and smaller 6.0mm pitch LED bulb is used, the resolution that can be expressed is only about VGA grade (640 * 480) There is a problem in that a high-quality image can not be realized.

On the other hand, LCD multi-vision and LED electronic signboards all have to be physically occupied in a venue, an exhibition hall, a venue, and the like.

Korea Patent Office Registration No. 10-0860186 (registered on September 18, 2008)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a projector capable of easily realizing a high resolution image using two or more projectors and projecting images using two or more projectors, And to provide a system and method for realizing an image space using a multi-projector capable of providing a high-quality image with very little sense of heterogeneity.

Another problem to be solved by the present invention is that there is no restriction on the installation place by using the interior space such as the wall surface or the floor inside the building as a screen without requiring a separate screen device occupying the indoor space in the building And a method and system for realizing an image space using a multi-projector capable of projecting images without distortion without changing the existing interior structure.

According to another aspect of the present invention, there is provided a method of implementing an image space using multiple projectors, the method comprising the steps of: a) allocating a specific space within a building to be projected by each of two or more projectors on a screen setting template; b) a screen area adjusting step of setting an interior mask on the screen setting template according to the shape of a specific space inside the building to be occupied by each of the projectors; c) loading a first content data on the data setting template and setting the first content data as a background layer; d) loading second content data on the data setting template and setting the second content data as an object layer; e) a projection data generation step of merging the background layer and the object layer into one layer and converting the merged object data into projection data; f) a data matching step of matching the projection data with the projector; g) distributing each of the projection data to each of the matched projectors; h) projecting the projection data matched in each of the projectors to a specific space inside the building; i) an image quality correction step of reducing a sense of heterogeneity between the two projection data projected in adjacent spaces among the projection data projected respectively in a specific space inside the building; And j) an illumination configuration step of controlling one or more illumination devices provided in the building through which the projection data is projected through the illumination setting template.

In this case, the e) generating the projection data may include: e-1) dividing the background layer by the number of the projectors to be matched; e-2) a first projection data generation step of merging one of the divided background layers and the object layer into one layer and converting the merged object into first projection data; And e-3) a second projection data generation step of converting the remaining background layer of the divided background layers into second projection data.

The b) screen area adjustment step may include: b-1) a marking point creation step of specifying a plurality of marking points along the boundary between the projection space and the interior mask space of the projector on the screen setting template; b-2) an outline generation step of generating and fine-tuning an outline by connecting a plurality of marking points on the screen setting template; And b-3) an interior mask generation step of storing an area enclosed by the outline as a masking layer of a single color, wherein d) after the second content data loading step, And merging a masking layer to reset the background layer to a single background layer from which the area enclosed by the outline is removed; And d-2) merging the object layer and the masking layer to reset the object layer to a single object layer from which an area outside the area enclosed by the outline is removed. .

In addition, the first content data may be video content or image content stored in a library in a content database, and the second content data may be video content, image content, or banner content stored in a library in a content database And is a content data.

In this case, c) the first content data loading step may be sequentially loaded with two or more first content data intervals according to a sequence determined from the content database.

In addition, in the loading of the second content data, the second content data loading step sequentially loads two or more second content data with an interval according to a sequence determined from the content database.

The second content data may be video content or image content that is transmitted in real time from an external camera electrically connected through a wireless or wired method.

And d) capturing the moving picture contents loaded with the second contents data at a predetermined interval and storing the same as image data after the step d) of loading the second contents data, .

In addition, the second content data may be moving image content or image content transmitted from an external storage device electrically connected through a wireless or wired method.

Further, in the j) lighting configuration step, the movement of a person is detected by one or two or more sensors provided in a building in which the projection data is projected, and the projection of the projection data and the control of the lighting apparatus Interlocking.

According to an aspect of the present invention, there is provided an image space implementing system using multiple projectors, including: a projector having two or more projectors for projecting projection data on a specific space inside a building; One or more lighting devices for emitting light to a specific space inside the building; One or more acoustic devices for emitting sound data into a building; An AV control division for distributing and controlling the projection data and the sound data digitally processed to and from the projector and the sound apparatus, a lighting control division for controlling the lighting apparatus in cooperation with the AV control division, an input device and a display device And an interface implementation unit for providing an input / output interface for controlling the AV control division and the lighting control division to the user through the I / O division; And a content database in which a plurality of content data structured by categorizing moving picture contents, image contents, and banner contents into a background library or an object library is stored.

Here, the AV control division may include an image processor unit for loading content data and converting the content data into the projection data; A data distributing unit connected to the image processor unit through a serial communication network, the data distributor being connected to at least two of the plurality of projectors and the image processor unit via a video interface cable and transmitting the projection data generated by the image processor unit to the projector; A data matching unit connected to the at least two projectors and the data distribution unit via a serial communication network to control transmission of projection data generated at the image processor unit; A screen setting unit for setting an interior mask according to a shape of a specific space inside the building to be projected by the projector; And an image quality corrector for reducing a sense of heterogeneity between the two projection data projected into a space adjacent to each other by the projector.

The image processor may further include a data loading module for loading the content data onto a data setting template, a layer setting module for setting the content data loaded on the data setting template as a background layer or an object layer, A layer merging module for merging the background layer and the object layer into a single layer, and a layer merging module for merging the background layer and the object layer into the banner content transferred from the content database, And a banner input module including a text input by a user in real time through an input / output video.

The screen setting unit may include a marking point generating module that transmits a screen setting template to the sub control unit through the interface implementing unit so that a user can specify a plurality of marking points along a boundary of an interior mask to be set, An outline generation module for finely adjusting an outline generated by connecting a plurality of marking points on the screen setting template; and an outline generation module for setting the same area as a virtual area enclosed by the outline as a masking layer of a single color And the layer merging module of the image processor merges the background layer and the masking layer and then merges the object layer only into the masking layer portion of the background layer to create one layer .

The AV control division may further include an automatic transmission setting module for controlling the user to sequentially transmit a plurality of the content data stored in the content database according to a specific sequence to the data loading module of the image processor unit .

In addition, the AV control division may further include a first external device connection unit for supplying moving image contents or image contents, which are transmitted in real time via an external camera connected wirelessly or by wire, to the data loading module of the image processor unit .

The image processor may further include an image capturing module that captures moving picture contents supplied through the first external device connection unit at predetermined intervals and stores the captured moving image data as image data.

The AV control unit may further include a second external device connection unit that transmits content data to the data loading module of the image processor unit in a wireless or wired connection with an external storage device storing moving picture contents or image contents .

The lighting control division may further include a lighting control section including a power module through which the user controls the power of the lighting apparatus through the lighting setting template and a dimming module through which the user controls the brightness of the lighting apparatus through the lighting setting template .

In addition, the lighting control division may include a lighting device in a building space in which the movement of a person is detected by one or more sensors provided in the building, and a lighting controller of the lighting control division, And a sensor interlocking unit for controlling the data matching unit of the AV control division.

The present invention can set the image space so that the wall or the floor can be directly used on the screen without changing the existing interior facilities in the building, so that the cost of additional interior change can be reduced and a separate screen device is required The advantage is that the space utilization can be maximized.

In addition, according to the present invention, it is possible not only to set the image space accurately corresponding to the structure of the existing interior of the building, but also to set a separate image space distinguishable from other parts in a specific interior or building structure There are other advantages of being able to actively respond to various building structures.

Further, in the operation of two or more projectors, the present invention can smoothly process even a large amount of data without delays by controlling and matching projected data to necessary projectors, The image quality correction process is performed so that there is no sense of mutuality between the projection data. Thus, there is another advantage that a high-resolution image space having a very high image quality can be easily implemented.

In addition, the present invention not only projects an image using a projector but also has a lighting device in a space required inside the building and controls the complexity of the lighting device to harmonize the image and the lighting to generate a synergy effect. And a sensor for detecting a moving object, so that a special effect can be easily realized by controlling the illumination and the image along a moving path of a person.

In addition, the present invention is not only easy to implement various image spaces by storing various high-definition moving image data, image data, banner data, etc. into a library and storing them in a content database, It is possible to transmit moving picture data or image data in real time through the storage device and to instantly display the moving picture data, and various phrases can be imaged on the banner data in real time, so that various image spaces can be quickly and easily implemented There are advantages.

1 is a flowchart illustrating a method of implementing an image space using a multi-projector according to an embodiment of the present invention.
2 is a diagram for explaining a process of setting an interior mask according to an embodiment of the present invention.
3 is a diagram for explaining a process of configuring projection data according to an embodiment of the present invention.
4 is a conceptual block diagram of an image space implementation system using multiple projectors according to an embodiment of the present invention.
5 is a conceptual diagram of an AV control division according to an embodiment of the present invention.
6 is a block diagram of an AV control division according to an embodiment of the present invention.
7 is a block diagram of a lighting control division according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a flowchart illustrating a method of implementing an image space using multiple projectors according to an embodiment of the present invention. FIG. 2 is a diagram for explaining a process of setting an interior mask according to an embodiment of the present invention. Is a diagram for explaining a process of configuring projection data according to an embodiment of the present invention.

A method of implementing an image space using multiple projectors according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3. FIG.

First, two or more projectors are provided at specific locations inside a building for realizing an image space, and each of the projectors designates an area to be occupied by each of the projectors. The image is projected on the floor or the like as a screen.

At this time, each of the projectors may project an individual image in a space separated from each other, but a continuous image may be projected in the same space to realize a high-resolution image.

That is, if images of 1024 * 768 resolution are projected in the same space using two projectors, the entire image will have a high resolution of 2048 * 768, and when three projectors are used, the resolution of 3072 * 768 , And when the four projectors are used, it has a resolution of 4096 * 768. By using the method of realizing the image space using the multi projectors according to the present invention, it is possible to superimpose super high resolution image spaces such as 3K and 4K images as well as 2K images .

Further, although it is possible to configure the plurality of projectors to project an image in the same space, for example, one wall surface, two consecutive wall surfaces, a ceiling surface, a wall surface, a bottom surface, It is possible to construct a stereoscopic image space using a screen.

The number of the projectors and the installation place to implement the image space are determined in consideration of the internal structure of the building to realize the image space, the purpose of implementing the image space, the cost and the like, The position and size of an image projected from each of the projectors are finely set on a screen setting template so that the image can be precisely implemented to a desired resolution without being interrupted or overlapped (S100).

The screen setting template is implemented by a control server that controls the various devices including the projector and the like and is provided to the user and is programmed by an intuitive interface so that the user can easily set an image projected from each of the projectors .

On the other hand, the internal structure of a building, such as a wall that will generally serve as a screen, is often a square planar surface, but it may not. In other words, for example, a corner of a wall surface inside a building for realizing an image space may be closed in a three-dimensional curved surface shape. In such a case, if the projector projects an image to the corner of the wall surface, distortion occurs . Therefore, in this case, it is necessary to prevent the image from being projected near the corner of the curved wall surface.

That is, it is preferable that the screen area is adjusted in accordance with the shape of the space to project the image of the projector installed in the building (S110) A mask is set, and a monochromatic image or other image is projected on the masked part, not the original image.

FIG. 2 is a conceptual illustration of such a screen area adjustment step.

2 (a) shows an example in which the interior structure 11 is formed near the center of a wall surface 10 constituting a screen area 20 in which a projector is placed. When the interior structure 11 is present in the screen area 20, it is necessary to set an interior mask corresponding to the interior structure 11 to prevent the image from being distorted.

In order to set the interior mask on the interior structure 11, a user first views a plurality of marking points 30 on the screen setting template along the boundary of the interior structure 11 while viewing the image projected on the wall of the image target, .

The marking point 30 may be specified based on a part of the shape of the interior structure 11. After all the marking points 30 are specified, Respectively.

2 (a), the outline may be formed simply by connecting the marking points 30. However, the interior structure 11 may be formed by connecting the marking points 30, It is necessary to finely adjust the marking point 30 so as to form a curved line after connecting the marking point 30 linearly.

After the outline 40 is formed along the boundary of the interior structure 11, the interior of the outline 40 is set as an interior mask. That is, the masking layer 70 is formed by processing the interior mask area formed by the outline 40 with a monochrome color such as black or the like, and when the image is projected by the projector, the masking layer 70 is applied So that the original image is not projected on the portion where the interior mask is set.

As described above, after designating and adjusting the screen area occupied by a plurality of projectors on the screen setting template, a step of constructing an image to be projected by the projector is performed. This is accomplished by loading the content data on the data setting template and converting it into projection data.

Here, the content data refers to various content sources such as various moving picture contents and image contents, and may be content data stored in a content database included in the main server or transmitted from a separate external camera or an external storage device Or content data. The projection data is data actually transmitted to the projector and projected onto the screen area. The data may be simply the same data as the content data, but may be data obtained by processing the content data.

The user searches the content database to designate and select video content or image content that has been created in advance, or to specify video content or image content transmitted from an external camera or to store video content stored in an external storage device Image content is selected and selected.

In this case, the banner content may be created and stored in addition to general video content or image content in the content database. The banner content is a content including a certain phrase. When the user inputs an arbitrary phrase on the data setting template So that it can be reflected as it is.

The selected moving image content, image content, and banner content are loaded onto the data setting template with the first content data (S200), and the loaded first content data is set as a background layer (S210).

At this time, when only a single image is desired to be projected using the projector, projection data is generated using only the background layer (S400). When it is desired to project an individual image for each of the plurality of projectors, 1 content data are loaded and set as background layers, respectively (S200, S210).

However, there is a case where an image in which two images are combined by one projector is projected. In this case, the first content data is loaded and set as a background layer, and then the second content data is loaded again to be set as an object layer (S300, S310). The second content data may be stored in the content database or transmitted from an external camera or an external storage device.

After the second content data is loaded and the object layer is set, the background layer and the object layer are merged into one layer to generate the projection data (S400).

By creating projection data by merging the background layer and the object layer as described above, it is possible to implement various image spaces. One of the image contents stored in the content database is set as a background layer, Any one of the moving picture contents can be set as an object and generated as one projection data. In addition, it is also possible to set one of the image contents stored in the contents database as a background layer, to set the moving picture contents transmitted through the external camera as an object layer, to set the image contents transmitted from the external storage device as an object layer, It may be generated as projection data.

In addition, the first content data constituting the background layer and the second content data constituting the object layer may be fixed at a constant interval such as a slide show without being fixed.

That is, the first content data is designated as a group of image content stored in the content database, the image content is loaded onto the data setting template at a predetermined interval, and the image content is set as the background layer, The projection data including various image contents are automatically projected to the designated area through the projector.

As another example, the first content data constituting the background layer may be loaded and set as an image content, and the second content data constituting the object layer may be specified as a group of video contents stored in the content database When the moving picture content is loaded onto the data setting template with a predetermined interval and is set as the object layer and is merged with the background layer to be converted into projection data, projection data, in which various moving picture contents are automatically reproduced on a predetermined background, Will be projected to the designated area through

On the other hand, when it is desired to realize a high resolution image space in a specific space inside a building, it is necessary to project a single high resolution image to a plurality of projectors. That is, in order to project an ultrahigh-resolution image having a resolution of 3072 * 768 to the projector that projects the image of resolution 1024 * 768 as described above, three projectors will be necessary and an image of resolution 3072 * 768 is divided It will be necessary to transfer the data.

Therefore, in this case, it is necessary to load the first content data onto the data setting template and set it as a background layer, and then divide the background layer into three and convert them into projection data. That is, when a 3072 * 768 resolution image is set as a background layer by loading the first content data, the background layer is divided into three and converted into three projection data having 1024 * 768 resolution. Of course, when dividing the background layer, it may be possible to generate projection data by dividing the background layer into different resolutions as needed without dividing them uniformly at the same resolution.

In the case where the background layer is divided as described above, the second content data may be loaded onto the data setting template to be set as an object layer and merged. One of the divided background layers and the object layer is merged, And the remaining background layers are directly converted into projection data, respectively.

3A to 3B show an example of generating projection data according to the present invention.

FIG. 3A illustrates generation of presentation data by merging a background layer 50, which is image content, and an object layer 60, which is also image content. That is, the background layer 50 is divided into three, and is set as the first to third background layers 51, 52 and 53, and then the object layer 60 is merged into the first background layer 51 on the left side, 1 projection data 81 and the remaining second background layer 52 and third background layer 53 are generated as second projection data 82 and third projection data 83, respectively.

As described above, if there is an interior structure in the interior of the building, it is possible to set the interior mask so that the projection data is not projected on the interior mask, and further, a specific image may be projected in an area where the interior mask is set .

3B, the three layers of the background layer 50, the object layer 60 and the masking layer 70 are merged to form the content of the object layer 60 in the masking layer 70 The projection data 80 to which the data is projected is generated. An example of the image actually implemented is shown in FIG. 3C.

Thus, by generating the projection data 80 using the background layer 50, the object layer 60 and the masking layer 70 appropriately, it is possible to harmonize with the interior structure as much as possible without changing the existing structure inside the building So that the image space can be realized.

On the other hand, after the projection data 80 is generated, the projection data 80 is projected to an area occupied by each projector. In this case, as described above, in the present invention, Since the projection data 80 is generated, the amount of data to be transmitted to each projector is considerable.

Therefore, when the projection data 80 is simply transmitted to each of the projectors at the same time, a bottleneck phenomenon or data collision occurs, which affects a data transmission speed and the like. As a result, The possibility of causing a problem is increased.

In order to prevent this, the generated projection data 80 and the corresponding projectors are matched with each other (S500). In this data matching step, the projection data 80 of each of the plurality of projectors So that the projection data 80 is transmitted to the projector requiring no delay or data loss.

Through the data matching step, the projection data 80 is distributed to the projector, and the projector projects the transmitted projection data 80 onto the screen area according to the preset setting.

At this time, when the 3072 * 768 resolution image is divided into three and generated and distributed as the projection data 80 as described above, each of the projection data 80 is divided into three pieces of projection data 80 Therefore, each image projected on the screen area inside the building is not a single image but three divided images may show some heterogeneity.

In addition to the case of dividing and projecting one image, there may be a case where different images are projected adjacent to each other. In this case, it is needless to say that more heterogeneous feeling can be felt between adjacent images. In this manner, the image quality correction step (S700) must be performed in order to reduce the sense of heterogeneity between the images projected from the respective projectors.

In general, when the projection data is projected by the projector, the image projected by the projector is installed in a specific space inside the building in which the projection data is projected, because the image quality may be affected by the amount of external light The illumination is controlled to perform the illumination setting step so that the image and the illumination are harmonized (S800).

In addition to manually controlling the lighting in the lighting setting step, it is also possible to detect the movement of a person moving to a specific space inside the building and actively control the image and the lighting accordingly.

That is, when a plurality of sensors are installed along a moving path of a person and the presence of a person is sensed by the sensor, the projection data is transmitted to the projector in the area where the sensor is installed and is projected, Or projecting the projection data to the projector, and sequentially projecting the projection data of a specific image along the sensor path sensed when the movement of a person is sensed by the sensor, and controlling the rough surface in conjunction with the projection data And so on.

Hereinafter, an embodiment of a method of implementing an image space using multiple projectors according to the present invention has been described. Next, an embodiment of a system for implementing an image space using multiple projectors according to the present invention will be described.

FIG. 4 is a conceptual block diagram of an image space implementation system using multiple projectors according to an embodiment of the present invention, FIG. 5 is a conceptual block diagram of an AV control division according to an embodiment of the present invention, FIG. 7 is a block diagram of a lighting control division according to an embodiment of the present invention. Referring to FIG.

4 to 7, an image space implementation system using multiple projectors according to an embodiment of the present invention includes a projector 1100 for projecting projection data to a screen area inside a building, A sound device 1300 for emitting sound data into the building and an integrated control for integrally managing and controlling the projector 1100, the lighting device 1200, and the sound device 1300 A server 2000, and a content database 3000 in which a plurality of pieces of content data are structured and stored in the form of a library.

At this time, the projector 1100 includes two or more, and all of the projectors 1100 may be configured to take up a single screen area. However, a plurality of the projectors 1100 may be divided into several groups It is also possible to constitute a separate screen area inside the building. That is, in the case of implementing an image space using all of the six projectors 1100, three projectors 1100 are divided into two groups, one group implements a screen region on one side wall of the building, and the other group implements a screen region on the other side wall Or to implement a screen area. The projector 1100 may be configured in various ways according to the structure inside the building or the purpose of implementing the image space, such that one group implements a screen area on one side wall and the other group implements a screen area on the bottom side.

In addition, the lighting apparatus 1200 may use a device having an illuminance and a color suitable for the purpose or place where the present system is installed, arrange an appropriate number in a required place according to the size and situation of the building, Apparatus 1300 also likewise places devices of suitable performance in the appropriate number of locations.

In the content database 3000, a plurality of content data necessary for generating projection data such as moving image content, image content, and banner content are stored. Rather than storing the various content data in a random manner, It is desirable to structure and make it possible to easily find and load necessary content data.

That is, for example, the content data stored in the content database 3000 is classified as being used as a background layer and an object layer, and structured into a background library and an object library, respectively. In the background library and the object library, they are classified into video content, image content, and banner content, and structured and classified into a wedding event, a birthday event, an advertisement event, and so on.

As the content database 3000 is structured and stored, the necessary content data in the content database 3000 can be quickly retrieved and loaded on the fly, as needed, while the video image is implemented in the projector 1100, So that it can be projected through the projector 1100.

The integrated control server 2000 includes an AV control division 2100 for managing and controlling the projector 1100 and the audio apparatus 1300 and a lighting control division 2200 for managing and controlling the lighting apparatus 1200 And a sub input / output division 2300 for providing an input / output interface that allows the user to manage and control the device.

The AV control division 2100 includes a screen setting unit 2110 for setting an interior mask according to the structure inside the building of the projector 1100, an image processor unit 2120 for generating projection data, A data matching unit 2130 that controls the transmission of projection data, a data distribution unit 2140 that transmits the projection data to the projector 1100, and the like.

At this time, the screen setting unit 2110 of the AV control division 2100 can view the image projected through the projector 1100 and specify the marking point at the border of the interior structure using the sub input / output division 2300 And a marking point generation module 2111 for transmitting a screen setting template to the interface implementing unit 250 of the sub input / output division 2300.

The user specifies the marking point through an input device 2310 such as a keyboard or a mouse through the screen setting template displayed through the display device 2320 of the sub input / output division 2300, The outline generation module 2112 of the screen setting unit 2110 connects the marking point to generate an outline surrounding the boundary of the interior structure. If the boundary of the interior structure is curved, the outline is also finely adjusted on the screen setting template so that the actual boundary and the outline are maximally matched.

When the creation of the outline on the screen setting template is completed, the area enclosed by the outline is set as a single color interior mask through the mask generation module 2113 and is stored as a masking layer.

The image processor 2120 of the AV control division 2100 includes a data loading module 2121 for loading content data on a data setting template and a layer setting module 2121 for setting the loaded content data as a background layer or an object layer A layer division module 2123 for dividing and resetting the background layer into two or more background layers, and a layer merging module 2124 for merging the background layer and the object layer into a single layer .

The data loading module 2121 receives the video contents, the image contents, the banner contents, and the like from the content database 3000 and loads the data on the data setting template.

In addition, there is a case where it is necessary to sequentially load a plurality of content data selected by the user and continuously generate projection data and project the image data through the projector 1100. In order to control the projector data, the AV0 control division 2100 automatically transmits A setting module 2160 is provided. The automatic transmission setting module 2160 controls the user to transmit a plurality of content data stored in the content database to the data loading module 221 of the image processor 2120 at a predetermined interval according to a specific sequence.

By thus configuring a plurality of content data to be loaded in a series of sequences, it is not necessary to control the user to load a plurality of content data in the content database 3000 during the image projection time, The content data automatically required by the control can be continuously loaded.

The data loading module 2121 of the image processor 2120 may receive the video contents or the image contents from the external camera 4000 or the external storage 5000 as well as the content database 3000 .

That is, the AV control unit 2100 can receive video content or image content captured by the external camera 4000 in a wireless or wired manner through the first external device connection unit 2170 of the AV control unit 2100, The second external device connection unit 2180 of the external storage device 5000 can receive the moving image content or the image content stored in the external storage device 5000 connected in a wireless or wired manner.

The external camera 4000 may be a general digital camera or a video camera. The external storage device 5000 may be a portable external hard disk device, an optical storage device such as a DVD, or the like.

The content data loaded from the content database 3000, the external camera 4000 and the external storage device 5000 through the data loading module 2121 is transferred from the layer setting module 2122 to the background layer or the object layer . If it is necessary to project the super-high-resolution content data to a plurality of projectors as described above, the super-high-resolution content data is loaded and set as a background layer, and the required number of the content data . What is important here is that the algorithm of the layer division module 2123 is configured not to divide content data quantitatively but to divide the screen itself into a plurality of background layers at a constant resolution for each frame in the case of moving picture contents.

Any one of the background layer and the object layer set in the layer setting module 2122 or the background layer divided in the layer division module 2123 is merged in the layer merging module 2124, And the merged layer is digitized into projection data and transmitted to the projector 1100. [ Of course, when the background layer is divided in the layer division module 2123, the remaining divided background layers in addition to the background layer merged with the object layer are also transferred to the projector 1110 as projection data.

Meanwhile, in the content database 3000, banner content is stored in addition to moving image content and image content. The banner content is configured to reflect the content of the banner content into projection data when the user inputs a certain phrase on the fly . Accordingly, when the banner content is loaded in the data loading module 2121 of the image processor 2120, the arbitrary text input by the user through the input device 2310 of the sub- A banner input module 2125 is provided in the image processor unit 2120 so as to be included in the image processing unit 2120.

The image processor module 2120 is connected to the data loading module 2121 through the first external device connection unit 2170. The image capturing module 2120 captures an image from the moving image content of the external camera 4000, (2126). The image capturing module 2126 may configure the user to capture an image arbitrarily in the moving image content transmitted from the external camera 4000. However, the image capturing module 2126 automatically captures the image from the moving image content at a predetermined interval, It is desirable to be able to configure the image set with the < RTI ID = 0.0 >

After the content data is converted into projection data through the image processor 2120, the projection data is transmitted to the projector 1100 and projected. The data distribution unit 2140 is provided in the AV control division 2100 in order to connect the image processor unit 2120 and the projector 1100. The data distribution unit 2140 is connected to the image processor unit 2120 And is connected to the projector 1100 and the image processor 2120 through a video interface cable. In addition, the data distribution unit 2140 is connected to the image processor unit 2120 through a local serial communication network to transmit and receive various signals and control commands, and transmits projection data to the image processor unit 2120 through the image interface cable. And transmits it to the projector 1100.

As described above, when the projection data is large in size, and the projection data transmission to the plurality of projectors 1100 is processed using only the data distribution unit 2140, a data bottleneck phenomenon or data collision occurs. In order to prevent this, it is necessary to provide the data matching unit 2130 in the AV control division 2100.

The data matching unit 2130 is connected to a plurality of the projectors 1100 and the data distribution unit 2140 through a serial communication network and transmits the projection data generated by the image processor unit 2120 and the projection data Is configured to control the connection between the projector 1100 and the data distribution unit 2140 requiring projection data after matching the projector 1100 to be transmitted. That is, the data matching unit 2130 serves as a signal lamp between the data distributor 2140 and the projector 1100, and switches the transmission path so that the respective projection data do not collide with each other or cause a bottleneck, .

On the other hand, when a plurality of projectors 1100 are used to implement an image space, there may be a case where there is a sense of heterogeneity between images projected on adjacent spaces due to the individual characteristics of the projectors 1100 or different content data .

Therefore, it is preferable that the image quality corrector 2150 be provided in the AV control division 2100 so as to reduce the heterogeneity of the images. The image quality corrector 2150 adjusts the white balance of each projector 1100 and adjusts the color, contrast, and the like according to each content data so that the gross texture is felt in the entire image.

In addition, it is also necessary to control a lighting device installed in a building in order to realize a more distinct image quality and an effective image space. The lighting control division 2200 of the integrated control server 2000 plays a role as described above .

The lighting control division 2200 basically provides a lighting setting template to the interface implementing unit 2330 of the sub input / output division 2300 so that the user can directly control the lighting apparatus 1200 and the like through the sub input / output division 2300 ).

The illumination control division 2200 includes a lighting control unit 2210 for controlling the operation and brightness of the illumination device 1200 and a sensor 2221 for sensing movement of a person to illuminate the illumination device 1200 and the projector 1100 And a sensor interlocking portion 2220 for interlocking the sensors.

The illumination control unit 2210 includes a power module 2211 for controlling the power of the illumination device 1200 through an illumination setting template and a dimming module for controlling the brightness of the illumination device 1200 through an illumination setting template 2212).

The sensor 2221 is installed in a specific passage through which a person passes within the building, and serves to grasp the movement path of a person. When the sensor 2221 senses the movement of a person, the sensor interlocking unit 2220 sends a signal to the data matching unit 2130 of the AV control unit 2100 to detect a movement of a person And controls the projector 1100 to project an image. The projector 1100 may be controlled by controlling the power module 2211 and the dimming module 2212 of the lighting control unit 2210 to operate the lighting device 1200 located on a path along which a person moves, To be in harmony with the projected image.

With such a configuration, when a person enters the space within a specific building, the projector 1100 and the lighting apparatus 1200 can be engaged with each other along a path along which the person moves, thereby realizing a special effect.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be apparent to those skilled in the art that various modifications, substitutions, and the like can be made without departing from the scope of the present invention.

10 - Wall 11 - Interior structure
20 - Screen area 30 - Marking point
40 - Outline 50 - Background layer
60 - object layer 70 - masking layer
80 - Projection data
1100 - Projector 1200 - Lighting system
1300 - Acoustic equipment
2000 - Integrated Control Server
2100 - AV Control Division
2110 - Screen setting section
2111 - Marking point generation module 2112 - Outline generation module
2113 - Mask generation module
2120 - Image processor unit
2121 - Data loading module 2122 - Layer setting module
2123 - Layer splitting module 2124 - Layer merging module
2125 - Banner input module 2126 - Image capturing module
2130 - Data matching unit
2140 - Data distribution section
2150 - image quality correction unit
2160 - Automatic Transfer Setup Module
2170 - First Exterior Device Connection 2180 - Second Exterior Device Connection
2200 - Lighting Control Division
2210 -
2211 - Power Module 2212 - Dimming Module
2220 - Sensor interlocking part
2221 - Sensor
2300 - Sub I / O Division
2310 - Input device
2320 - display device
2330 - Interface Implementation Department
3000 - Content database
4000 - External camera 5000 - External storage device

Claims (20)

a) a screen area designation step of allocating, on a screen setting template, a specific space within a building to be projected by each of two or more projectors;
b) a screen area adjusting step of setting an interior mask on the screen setting template according to the shape of a specific space inside the building to be occupied by each of the projectors;
c) loading a first content data on the data setting template and setting the first content data as a background layer;
d) loading second content data on the data setting template and setting the second content data as an object layer;
e) a projection data generation step of merging the background layer and the object layer into one layer and converting the merged object data into projection data;
f) a data matching step of matching the projection data with the projector;
g) distributing each of the projection data to each of the matched projectors;
h) projecting the projection data matched in each of the projectors to a specific space inside the building;
i) an image quality correction step of reducing a sense of heterogeneity between the two projection data projected in adjacent spaces among the projection data projected respectively in a specific space inside the building; And
and j) an illumination configuration step of controlling one or more illumination devices provided in a building in which the projection data is projected through an illumination setting template. Way. The method according to claim 1,
E) generating the projection data,
e-1) dividing the background layer by the number of the projectors to be matched;
e-2) a first projection data generation step of merging one of the divided background layers and the object layer into one layer and converting the merged object into first projection data; And
and e-3) a second projection data generation step of converting the remaining background layers of the divided background layers into second projection data. The method according to claim 1,
B) adjusting the screen area comprises:
b-1) a marking point generating step of specifying a plurality of marking points along the boundary between the projection space and the interior mask space of the projector on the screen setting template;
b-2) an outline generation step of generating and fine-tuning an outline by connecting a plurality of marking points on the screen setting template; And
b-3) an interior mask generation step of storing the area enclosed by the outline as a masking layer of a single color,
D) after the second content data loading step,
d-1) merging the background layer and the masking layer to reset the background layer to a single background layer from which the area enclosed by the outline is removed; And
and d) merging the object layer and the masking layer to reset the object layer to a single object layer from which an area outside the area enclosed by the outline is removed from the object layer. A method for realizing image space using multiple projectors. The method according to claim 1,
The first content data is video content or image content stored in a library in a content database,
Wherein the second content data is one of video content, image content, and banner content stored in a library in a content database. The method of claim 4,
C) the first content data loading step comprises:
Wherein a plurality of first content data are sequentially loaded with intervals between two or more first content data according to a sequence determined from the content database. The method of claim 4,
D) loading the second content data comprises:
And sequentially loading two or more second content data with intervals in accordance with a sequence determined from the content database. The method of claim 4,
Wherein the second content data comprises:
Wherein the video content or image content is transmitted in real time from an external camera electrically connected through a wireless or wired system. The method of claim 7,
D) after the second content data loading step,
d ") capturing the moving picture contents loaded with the second contents data at a predetermined interval and storing the captured moving picture contents as image data. The method of claim 4,
Wherein the second content data comprises:
Wherein the video content or image content is transmitted from an external storage device electrically connected through a wireless or wired system. The method according to claim 1,
And j)
Wherein a projection of the projection data and a control of the lighting apparatus are interlocked by sensing movement of a person by one or more sensors provided in a building in which the projection data is projected. How to implement video space. Two or more projectors projecting projection data on a specific space inside the building;
One or more lighting devices for emitting light to a specific space inside the building;
One or more acoustic devices for emitting sound data into a building;
An AV control division for distributing and controlling the projection data and the sound data digitally processed to and from the projector and the sound apparatus, a lighting control division for controlling the lighting apparatus in cooperation with the AV control division, an input device and a display device And an interface implementation unit for providing an input / output interface for controlling the AV control division and the lighting control division to the user through the I / O division; And
And a content database in which a plurality of content data structured by categorizing video content, image content, and banner content into a background library or an object library is stored. The method of claim 11,
In the AV control division,
An image processor for loading content data and converting the data into the projection data;
A data distributing unit connected to the image processor unit through a serial communication network, the data distributor being connected to at least two of the plurality of projectors and the image processor unit via a video interface cable and transmitting the projection data generated by the image processor unit to the projector;
A data matching unit connected to the at least two projectors and the data distribution unit via a serial communication network to control transmission of projection data generated at the image processor unit;
A screen setting unit for setting an interior mask according to a shape of a specific space inside the building to be projected by the projector; And
And an image quality corrector for reducing a degree of heterogeneity between the two projection data projected in a space adjacent to each other by the projector. The method of claim 12,
Wherein the image processor unit comprises:
A data loading module for loading the content data onto a data setting template; a layer setting module for setting the content data loaded on the data setting template as a background layer or an object layer; A layer merging module for merging the background layer and the object layer to generate a single layer; and a layer merging module for merging the background layer and the object layer into the banner content transmitted from the content database through the sub input / And a banner input module that includes a text input in real time. The method of claim 12,
The screen setting unit,
A marking point generating module that transmits a screen setting template to the sub control unit through the interface implementing unit so that a user can specify a plurality of marking points along a boundary of an interior mask to be set; An outline generation module for fine-tuning the outline generated by the outline on the screen setting template, and a mask generation module for setting and storing a masking layer of the same color as a virtual color area of the outline, ≪ / RTI &
Wherein the layer merging module of the image processor unit comprises:
And merges the object layer only into the masking layer portion of the background layer after merging the background layer and the masking layer to generate a single layer. 14. The method of claim 13,
In the AV control division,
Further comprising an automatic transmission setting module for controlling the user to sequentially transmit a plurality of the content data stored in the content database to the data loading module of the image processor unit with an interval according to a specific sequence. Image Space Implementation System. 14. The method of claim 13,
In the AV control division,
Further comprising a first external device connection unit for supplying, to the data loading module of the image processor unit, moving image contents or image contents transmitted in real time via an external camera connected wirelessly or by wire, . 18. The method of claim 16,
Wherein the image processor unit comprises:
Further comprising an image capturing module for capturing moving picture contents supplied through the first external apparatus connection unit at predetermined intervals and storing the captured moving image contents as image data. 14. The method of claim 13,
In the AV control division,
Further comprising a second external device connection unit for wirelessly or wiredly connecting with an external storage device storing moving picture contents or image contents and transmitting content data to a data loading module of the image processor unit Spatial implementation system. The method according to any one of claims 11 to 18,
The lighting control division,
And a dimming module for allowing the user to control the brightness of the illumination device through the illumination setting template, wherein the dimming module controls the brightness of the illumination device, Image Space Implementation System Using. The method of claim 19,
The lighting control division,
A lighting control unit of the lighting control division and a data matching unit of the AV control division are provided so that a lighting device in a building space in which a movement of a person is detected by one or two or more sensors provided in the building, And a sensor interlocking unit for controlling the image sensor.

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