KR102170367B1 - Method and system for outputting image with plurality of image displaying devices - Google Patents

Abstract

The present invention relates to a system and method for outputting an image to a plurality of image display devices. The video output system of the present invention includes a transmission subsystem that processes and transmits image data, and a reception subsystem that receives and outputs the processed image data from the transmission subsystem, and the reception subsystem includes a plurality of image display devices. , The plurality of image display devices are sequentially connected, the transmission subsystem scales the image data based on the image output capability of the receiving subsystem, and represents the parts to be output from each of the plurality of image display devices. It is configured to divide the image data into blocks, reconstruct the order of the divided image data blocks based on the order in which the image display devices are connected, and transmit the reconstructed image data blocks to the receiving subsystem in the reconstructed order, and receive The subsystem may be configured to store the received image data in an image storage unit of the corresponding image display device according to a predetermined rule, or to transmit the received image data to the image display device after being connected to the corresponding image display device.

Description

Method and system for outputting an image to a plurality of image display devices {METHOD AND SYSTEM FOR OUTPUTTING IMAGE WITH PLURALITY OF IMAGE DISPLAYING DEVICES}

The present invention relates to a method and system for outputting an image to a plurality of image display devices. More specifically, it relates to an image output method and system in which image data is processed before transmission to image display devices so that image display devices can output an appropriate image without performing a complicated image processing operation.

A video display device is a device that outputs input image data as an image that can be viewed from outside, and is widely used to deliver visual information.
As video display devices are used for various purposes, demand for video display devices capable of displaying large-area images continues to arise, but the size of a screen that can be implemented with one device is limited due to technical and cost issues. Will exist.
Accordingly, in order to overcome the size of an image that can be represented by a single image display device, a method of expressing an image of a larger size by configuring several image display devices as a single system has been adopted.
A system implemented in this way is called a video wall system or a multivision system. In the multi-vision system, each display device is assigned an ID, and after each display device receives all of the image data, it determines a part of the image corresponding to its ID to determine the location of the image to be output. In addition, each display device can appropriately output an intended image only by performing complex image processing such as adjusting the image appropriately to the image output condition of the device.
In other words, in order to implement such a multi-vision in the related art, an original image having a large size is transmitted to each of a plurality of displays, and then divided into small image parts by each display device, selected, and output. The image had to be displayed without interruption. For this reason, a large amount of data constituting the original image must be transferred to each of the displays, and each display must perform image processing to reconstruct the received image to suit its processing environment, so it has a fairly high level of specifications. It has been taken for granted that there should be, and complicated techniques to control the display of these multiple devices in full detail.
As an example, Korean Patent No. 1915311 provides a method of automatically assigning IDs to display devices in a matrix form using a mathematical algorithm in a multi-vision in which a plurality of display devices are connected and installed. According to this configuration, the user can easily recognize the ID of each display device, and installation of a multi-vision related to ID assignment of the display device can be simplified.
However, even in the same manner as above, since each display still needs to receive the entire image and transmit the entire image to the next display, not only each display must have high data processing capability, but also each device must be equipped with a scaler. Needs to be.
In addition, ID allocation is still required for each display, and since the position of an image to be outputted according to the allocated ID must be grasped in each display, the amount of information to be processed in each display increases.
Accordingly, the hardware and software specifications that each display device of the multi-vision system must have increases, and the larger the screen size implemented by the multi-vision system increases, the higher the equipment cost and the complexity of the system control. .

The present invention, when dividing a large-area image into a plurality of partial images and displaying the same number of image display devices, affects the quality of partial and large-area images while limiting the required specifications of each image display device to a minimum. This is to solve technical difficulties that are difficult to be compatible with each other in order not to cause problems.
In other words, the present invention devised a new multi-vision system and method that can reduce the amount of image processing performed in each video display device and save the specifications of the device, so that each video display device in the conventional multi-vision system The task is to overcome the problem that IDs have to be assigned and the entire image processing, image scaling, and output image selection operations have to be performed for each image display device.
More specifically, in a system for outputting an image to a plurality of image display devices, the present invention enables each image display device to output a suitable image allocated to it without an ID assignment task for each image display device. It is an object to provide a system and method that can be used.
In addition, in a system for outputting an image to a plurality of image display devices, the present invention enables each image display device to output a suitable image allocated to itself without performing a complicated image processing task and image selection task. It aims to provide a system and method.
Another object of the present invention is to reduce hardware and software requirements of a part that performs transmission/reception within an image output system by allowing only image data of a size to be output from actual image display devices to be transmitted and received in an image output system. .
In addition, the present invention simplifies the function performed by the video display device in a system for outputting an image to a plurality of video display devices, thereby reducing the required specifications for the video display device, which is significantly lower than the existing multi-vision system. An object of the present invention is to provide an image output system and method composed of a plurality of image display devices.

In order to solve the technical problem for achieving the above object, the inventors of the present invention reduce the waste of resources transmitted by overlapping the entire image data to each conventional image display device, and greatly increase the role of each image display device and its own image processing. A method that does not affect the quality of the image while reducing it is proposed. In other words, the present inventors allow many image processing tasks such as image scaling, image segmentation, and reconstruction of the divided image sequence to be pre-processed in the transmission subsystem and simultaneously transmit the pre-processed image data to the image display device in a resource efficient manner. , In the video display device of the receiving subsystem, a system that outputs the received video data is relatively simple.
In an embodiment of the present invention, a system for outputting an image to a plurality of image display devices may include a transmission subsystem and a reception subsystem including a plurality of image display devices.
Here, the transmitting subsystem may process the image data and transmit it to the receiving subsystem, and the receiving subsystem may receive the processed image data from the transmitting subsystem and output an image.
The transmitting subsystem scales the original image data based on the image output capability of the receiving subsystem, and displays the scaled image data to be output from each of the plurality of image display devices included in the receiving subsystem. The image data may be divided into blocks, the order of the divided image data blocks may be reconstructed based on the order in which the image display devices are connected, and the reconstructed blocks of the image data may be sequentially transmitted to the receiving subsystem.
Here, the image output capability of the receiving subsystem is the sum of the resolutions of the plurality of image display devices, and each of the divided image data blocks may have the same resolution as the resolution of the image display device to which the corresponding image data is to be output.
In addition, the video output capability of the receiving subsystem is determined based on the resolution information of each video display device of the receiving subsystem, and the transmitting subsystem is based on the resolution information and the number of video display devices to output the video data. Can be scaled.
Each video display device of the receiving subsystem receives blocks of image data reconstructed from the transmission subsystem and stores them in the video storage unit of the video display device according to a predetermined rule, or to the next video display device connected to the video display device. Can be configured to deliver.
Here, the transmission subsystem is additionally configured to transmit a synchronization signal after all of the reconstructed image data have been transmitted to the video display devices, and each video display device of the receiving subsystem receives the synchronization signal. It may be additionally configured to simultaneously output image data stored in the image storage unit.
In addition, each video display device of the receiving subsystem includes a pixel counter that counts the number of pixels of the image represented by the received video data in order to calculate whether the video information of the received video data is as much as the video display device can output. I can.
In one embodiment of the present invention, each of the video display devices of the receiving subsystem determines whether the video display device has received as much image data as it can output, determines whether all the images to be output are received, and additionally received video data. Can be transferred to the next video display device.
Here, each video display device of the receiving subsystem receives image data representing the number of pixels corresponding to the resolution of the video display device, stores it in the image storage unit of the video display device, and stores the resolution of the video display device. When additional image data is received after receiving image data representing an image corresponding to the number of pixels corresponding to the appropriate number of pixels, the additional image data may be connected to the corresponding image display device and then transmitted to the image display device.
In another embodiment of the present invention, each video display device of the receiving subsystem receives image data representing the number of pixels corresponding to the resolution of the video display device, and stores it in an image storage unit of the video display device, When additional image data is received, the image data previously stored in the image storage unit is connected to the image display device and then transferred to the image display device, and the image display device receives additional image data as many as the number of pixels suitable for the resolution of the image display device. It may be configured to repeat the operation of storing in the image storage unit of.
An image data providing apparatus according to another exemplary embodiment of the present invention may be a device that provides image data to be output from a plurality of image display devices sequentially connected.
The image data providing apparatus includes an image scaler that scales image data based on a sum of resolutions of a plurality of image display devices, and portions to be output from each image display device among a plurality of image display devices. An image reconstruction unit that divides the displayed image data into a plurality of blocks and reconstructs the divided image data according to the order in which the image display devices are connected, and displays the first image among the plurality of image display devices according to the reconstructed order It may include an image transmission unit configured to sequentially transmit to the device.
A method for outputting an image from a plurality of image display devices performed by an image output system including a transmission subsystem and a reception subsystem according to an embodiment of the present invention comprises: a transmission subsystem receiving image data from the reception subsystem Scaling to match the image output capability of, dividing the scaled image data in the transmission subsystem into portions to be output from each image output device among a plurality of image display devices, and image data divided in the transmission subsystem Reconfiguring the image output devices according to the order in which they are connected, sequentially transmitting the image data reconstructed in the transmitting subsystem to the receiving subsystem, and receiving the reconstructed image data in each image display device of the receiving subsystem. , Storing the video in an image storage unit of the video display device according to a predetermined rule, or transmitting it to the video display device after being connected to the video display device.
The image output method according to an embodiment of the present invention may further include counting the number of pixels of an image represented by image data received from each image display device between the receiving step and the transmitting step.
Here, the image output capability of the receiving subsystem is determined based on resolution information of each image display device of the receiving subsystem, and the scaling step includes image data based on the resolution information and the number of image display devices to output the image data. It may include the step of scaling.
In addition, the image output capability of the receiving subsystem is the sum of the resolutions of the plurality of image display devices, and each of the divided image data may have the same resolution as the resolution of the image display device to which the corresponding image data is to be output.
Here, the image output method according to an embodiment of the present invention includes transmitting a synchronization signal from a transmission subsystem to the reception subsystem after all reconstructed image data are transmitted to the image display devices, and When each video display device receives a synchronization signal, the step of simultaneously outputting the image data stored in the image storage unit of each video display device may be further included.
In the image output method according to an embodiment of the present invention, storing the image data reconstructed in the image storage unit of the corresponding image display device or transferring the image data to the next image display device connected to the corresponding image display device includes: Receiving image data corresponding to the number of pixels corresponding to the resolution of the image display device from the display device and storing it in the image storage unit of the image display device, and when additional image data is received from each image display device, the image is displayed. It may include transmitting the additional image data to the next video display device connected to the device.
In the image output method according to an embodiment of the present invention, storing the image data reconstructed in the image storage unit of the corresponding image display device or transferring the image data to the next image display device connected to the corresponding image display device includes: Receiving image data corresponding to the number of pixels corresponding to the resolution of the image display device from the display device and storing it in the image storage unit of the image display device, and when additional image data is received from each image display device, the image storage unit The previously stored image data may be transferred to the next image display device connected to the corresponding image display device, and the additional image data may include storing in the image storage unit of the image display device as many as the number of pixels suitable for the resolution of the image display device. have.

According to an image output system and method according to an embodiment of the present invention, unlike a conventional multi-vision system, an ID does not need to be assigned to each image display device, and a complex image processing task needs to be performed for each image display device. As a result, it is possible to provide an image output system and method capable of using a simplified image display device.
In addition, the video output system and method according to the embodiment of the present invention are assigned to each video display device to itself even without ID assignment for each video display device in a system for outputting an image to a plurality of video display devices. It is possible to provide a system and method capable of outputting a suitable image.
In addition, the image output system and method according to the embodiment of the present invention, in a system for outputting an image to a plurality of image display devices, each image display device does not perform a complex image processing task and image selection task itself, It is possible to provide a system and method capable of outputting an appropriate image allocated to a user.
In addition, the video output system and method according to the embodiment of the present invention is a hardware component of a part that performs transmission/reception in the video output system by transmitting and receiving only video data of a size to be output from actual video display devices in the video output system. In addition, by lowering the software requirements and reducing the amount of processed data, a more efficient video output system can be constructed.
In addition, the video output system and method according to the embodiment of the present invention can reduce the required specifications for the video display device by simplifying the function performed by the video display device in a system for outputting an image to a plurality of video display devices. In addition, compared to the existing multi-vision system, it is possible to provide an image output system and method composed of a plurality of image display devices at a significantly lower cost.
In addition, according to the video output system and method according to an embodiment of the present invention, since most of the complex image processing is performed in the transmitting subsystem and the video output operation is relatively simple in the receiving subsystem, the overall system control complexity is reduced. , It is possible to output an image to a plurality of image display devices without complicated settings for an image to be output.

1 is a front view of a system for outputting an image from a plurality of image display devices according to an embodiment of the present invention.
FIG. 2 is a view showing a rear exterior of a system for outputting an image from a plurality of image display devices according to an embodiment of the present invention.
3 is a block diagram of a system for outputting an image according to an embodiment of the present invention.
4 is a diagram illustrating a scaling operation in a system for outputting an image according to an embodiment of the present invention.
5 is a diagram illustrating an image reconstruction operation and a transmission operation in a system for outputting an image according to an embodiment of the present invention.
6 is an internal block diagram of a plurality of image display devices according to an embodiment of the present invention.
FIG. 7 is a diagram for explaining a method in which images reconstructed in a system for outputting an image according to an embodiment of the present invention are transmitted to each image display device.
8 is a diagram for explaining a method in which images reconstructed in a system for outputting an image according to another embodiment of the present invention are transmitted to each image display device.
9 is a flowchart illustrating a method of transmitting image data to each image display device in a system for outputting an image according to an embodiment of the present invention.
10 is a flowchart illustrating a method of transmitting image data to each image display device in a system for outputting an image according to another exemplary embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings. The present invention may be implemented in various different forms, and is not limited to the embodiments described herein. In the following embodiments, parts that are not directly related to the description are omitted in order to clearly describe the present invention, but it does not mean that the omitted configuration is unnecessary when implementing an apparatus or system to which the spirit of the present invention is applied. . In addition, the same reference numerals are used for the same or similar elements throughout the specification.
In the following description, terms such as first and second may be used to describe various components, but the components should not be limited by the terms, and the terms refer to one component from another component. It is used for identification purposes only. In addition, in the following description, expressions in the singular include plural expressions, unless the context clearly indicates otherwise.
In the following description, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other It is to be understood that the presence or addition of features, numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance the possibility of being excluded.
1 and 2 illustrate the appearance of a system for outputting an image in a plurality of image display devices according to an embodiment of the present invention.
The system for outputting an image includes a transmission subsystem 100 that processes and transmits image data, and a reception subsystem including a plurality of image display devices 210, 220, 230, and 240 that output received image data ( 200).
The multi-vision system or video wall system as shown in FIGS. 1 and 2 is a system in which a plurality of image display devices display images together, not one image display device.
Accordingly, one image frame is divided for each area to correspond to each image display device 210, 220, 230, 240, and each image display device 210, 220, 230, 240 separates the divided image frame. It is marked with Due to such an operation, the image output system may display one image frame on a large screen through a plurality of image display devices.
1 and 2 illustrate an embodiment in which four image display devices are arranged in a 2x2 matrix form, this is only an example, and the number and arrangement method of the image display devices may be variously changed and applied.
In an embodiment of the present invention, among a plurality of image display devices 210, 220, 230, and 240 arranged in a 2x2 matrix form, the first image display device 210 is at the upper left and the second image display device 220 Is disposed at the upper right, the third video display 230 is disposed at the lower left, and the fourth video display 240 is disposed at the lower right.
Referring to FIG. 1, it is understood that one image can be displayed by a plurality of image display devices by dividing one image into parts and outputting it from each image display device 210, 220, 230, 240. Able to know.
In one embodiment of the present invention, the image frame is divided into 2x2 corresponding to the arrangement of each of the image display devices 210, 220, 230, 240, and each divided region of the image frame is an image corresponding to a corresponding position. It is displayed on the display devices 210, 220, 230, 240. That is, of the divided regions of the image frame, the upper left region is on the first image display device 210, the upper right region is on the second image display device 220, the lower left region is on the third image display device 230, and The lower area is output by the fourth image display device 240.
Referring to FIG. 2, it can be seen that the transmission subsystem 100 and the reception subsystem 200 are connected, and a plurality of image display devices 210, 220, 230, and 240 may be sequentially connected. Meanwhile, in FIG. 2, the transmission subsystem 100 and the reception subsystem 200 are connected by wire, but this does not exclude wireless connection.
In this embodiment, the transmission subsystem 100 is connected to the first video display device 210 through the first cable 21, and the first video display device 210 is connected to the second video display device 210 through the second cable 22. The video display device 220 is connected, the second video display device 220 is connected to the third video display device 230 through a third cable 23, and the third video display device 230 is connected to the fourth video display device. It is connected to the fourth video display device 240 through a cable 24.
The first image display device 210, which is the highest priority among the image display devices, receives image data from the transmission subsystem 100, and the image data is sequentially transmitted to the next connected image display devices 220 to 240. have.
For such data transmission, each of the video display devices 210, 220, 230, and 240 may have input ports 210a, 220a, 230a, 240a and output ports 210b, 220b, 230b, and 240b.
In FIGS. 1 and 2, the transmission subsystem 100 is shown to be disposed separately from the reception subsystem 200, but the transmission subsystem 100 may be integrally configured with the reception subsystem. For example, the transmission subsystem 100 may be configured to be embedded in the first video display device 210 among video display devices.
The transmission subsystem 100 may be a separate device such as a set-top box or a media player as an example, and is referred to as a subsystem in the sense that it is in charge of image processing and transmission in a multi-vision system. Can be. Meanwhile, the transmission subsystem 100 may be referred to as an image data providing device in the sense of processing and providing image data to be transmitted to image display devices sequentially connected.
Also, the configuration of the image display devices is not limited to the illustrated arrangements and numbers. As long as they are sequentially connected, the image output system according to the present invention may be configured with various arrangements and numbers of image display devices as needed.
In addition, the image display devices may be LCD, PDP, and OLED displays, and further, may include a projector that projects an image.
3 is a block diagram of an image output system according to an embodiment of the present invention.
The transmission subsystem 100 may include an image scaler 110, an image reconstruction unit 120, and an image transmission unit 130. Although not shown in FIG. 3, other components such as a user input unit and a data storage unit may be used. It may include more.
The original image data processed by the transmission subsystem 100 may be received and processed in real time, such as a TV broadcast, or the original image file is stored in the data storage unit of the transmission subsystem 100, and the stored data is processed. It could be.
4 and 5 are diagrams illustrating a scaling operation, an image reconstruction operation, and an image transmission operation performed in the transmission subsystem 100 of the system for outputting an image according to an embodiment of the present invention.
The image scaler 110 scales an image to be output according to the image output capability of the receiving subsystem 200 in which the image is to be output. In addition to the resolution, the video output capability of the receiving subsystem 200 may be a limiting condition related to various video output such as the number of video display devices, aspect ratio, scanning rate, and expressible colors. Capabilities can be determined by various combinations of them.
As an example, the image output capability of each of the video display devices 210, 220, 230, and 240 of the receiving subsystem 200 is determined by the video display devices 210, 220, 230, and 240 of the receiving subsystem 200. ) May be determined based on the resolution information, and the transmission subsystem 200 may scale the image data based on the resolution information and the number of image display devices to output the image data.
For example, as shown in FIG. 4, the original image data 11 to be output is a 4K image of 3840 X 2160, and four image display devices constituting the receiving subsystem 200 each have a resolution of 720 X 480. If so, the image scaler 110 may scale the image data 11 of 3840 X 2160 to the image data 13 with a resolution of (720 X 480) X 4 = 2880 X 1920.
In addition, the image output capability of the receiving subsystem 200 is the sum of the resolutions of the plurality of image display devices 210, 220, 230, and 240, and each of the divided image data is the image display device to which the corresponding image data is output. It can have the same resolution as the resolution.
In the case of FIG. 4, the image output capability of the receiving subsystem 200 is 2880 X 1920, and the image data to be transmitted to the receiving subsystem 200 is divided into 4 blocks, and each block of image data is 720 X. It can have a resolution of 480.
The video output capability of the receiving subsystem 200 may be preset by the operator when the video output system is installed and stored in the transmitting subsystem 100, or the transmitting subsystem 100 may receive the receiving sub-system at a stage prior to image processing. Information may be collected and identified through communication with the system 200.
Since the image data is pre-scaled to be suitable for the receiving subsystem 200 through the image scaler 110 of the transmitting subsystem 100, the transmitting subsystem 100 uses the receiving subsystem 200, not the original image data itself. Image data with resolution as high as it can be output can be transmitted.
Accordingly, the hardware and software specifications of the data transmission/reception unit between the transmission subsystem 100 and the reception subsystem 200 and the data transmission/reception unit in the reception subsystem 200 can be kept low, which is It can lead to cost reduction of the overall system.
The image reconstruction unit 120 divides the image data into a plurality of blocks to be output from each image display device according to an operation method of the reception subsystem 200 and reconstructs the order of blocks of the divided image data.
Since the order in which the image data is reconstructed and transmitted in the transmission subsystem 100 determines which image portion is to be output from which image display device, the order of the reconstructed image data blocks is displayed in the receiving subsystem 200 It should be determined taking into account the order in which devices are connected.
In addition, in which video display device blocks of video data input to the receiving subsystem 200 are finally stored in accordance with rules related to the operation of storing video data received from the video display device or transferring it to the next video display device. It changes.
Therefore, the image reconstruction unit 120 of the transmission subsystem 100 is the final transmission result of the image data according to the operation rule of the image display devices 210, 220, 230, 240 of the receiving subsystem 200, respectively. It is necessary to determine the order of blocks of image data reconstructed so that blocks of image data corresponding to the image display device can be stored.
In the following, for convenience of description of a method of reconstructing image data, it is assumed that the four image display devices 210, 220, 230, and 240 of the receiving subsystem 200 are connected as shown in FIG. 2. In addition, each video display device stores the first input image data only as much as the size suitable for the resolution that the video display device can output, and the additional video data that is subsequently input is transferred to the next video display device. It is assumed that it is set in advance.
The operation rules of the video display device as described above may be already set and shipped at the time of manufacture of the video display device, or may be set by the operator at the time of installation of the multi-vision system, and can be adjusted by the user later as necessary. It may be configured to be.
Referring to FIG. 5, the image reconstruction unit 120 of the transmission subsystem 100 divides the scaled image data 13 into four regions or blocks, and blocks of the divided image data are the upper left image 1, The upper right image 2, the lower right image 4, and the lower left image 3 are reconstructed in order.
The blocks of the image data 17 reconstructed by the image reconstruction unit 120 are sequentially transmitted to the receiving subsystem 200 through the image transmission unit 130 according to the arrangement order.
As shown in FIG. 5, the blocks of the reconstructed image data 19 transmitted to the receiving subsystem 200 are transmitted first with the image data block disposed on the rightmost side, and the image data block disposed on the leftmost side, as shown in FIG. Sent later.
The reconstructed image data 19 sequentially transmitted to the receiving subsystem 200 does not separately include location information or ID information on the image display device to be output, and the order of blocks of the divided and reconstructed image data itself is It is possible to determine which image data portion is to be output to which image display device.
Accordingly, the amount of data transmitted and received in the image output system decreases, and the image display devices 210, 220, 230, and 240 of the receiving subsystem 200 sequentially order the received image data without ID assignment or separate image processing. It can be saved as it is and output an image of a suitable area.
6 is an internal block diagram of a plurality of image display devices according to an embodiment of the present invention.
The first image display device 210 of the receiving subsystem 200 includes an image receiving unit 211 receiving image data transmitted from the transmitting subsystem 100, and a pixel counter counting the number of pixels included in the received image data. (213), an image storage unit 215 for storing received image data, an image output unit 217 for outputting stored image data, and a second image display device connected next to image data to be output from another image display device It may include an image transmission unit 219 transmitted to the 220.
The image receiving unit 211 may sequentially receive the reconstructed image data transmitted from the transmission subsystem, and the pixel counter 213 may count the number of pixels of the image indicated by the received image data.
In the image data, there is a signal indicating that each pixel data is valid data representing one pixel, and the pixel counter 213 can read this signal and calculate the number of pixels received by the first image display device 210. have. In another example, since there is a signal for displaying it for every predetermined number of pixel data in the image data, the pixel counter 213 may read such a signal and calculate the number of received pixels in a predetermined number of units.
According to the operation rule assumed in an embodiment of the present invention, the first image display device 210 receives image data corresponding to the number of pixels corresponding to the resolution that the first image display device 210 can output, and It is stored in the image storage unit 215 of the display device 210.
When additional image data is received by the first image display device by exceeding the number of pixels corresponding to the resolution that the first image display device 210 can output, the next image display device 220 connected to the corresponding image display device 210 The additional image data is transmitted to.
For example, if the resolution of the first image display device 210 is 720 X 480, the pixel counter 213 counts until the number of pixels of the image data received through communication with the image receiver 211 reaches 345,600, It is stored in the storage unit 215, and the additionally received image data is transmitted to the second image display device through the image transmission unit 219.
Other video display devices of the receiving subsystem 200 may have the same configuration as the above-described first video display device 210 and operate on the same principle.
As shown in FIG. 6, the image display devices 210, 220, 230, and 240 of the reception subsystem 200 according to an embodiment of the present invention simply display image data sequentially received according to a predetermined rule. By storing the image in the image storage unit or transmitting it to the next image display device, a portion of the image to be originally output may be stored in an appropriate image display device.
When portions of image data suitable for all image display devices are stored, images stored in each image display device are output according to a synchronization signal received from the transmission subsystem 100 to implement one image as a whole.
According to this configuration, since a separate image scaler or image reconstruction unit is not required in the image display device, functions performed by the image display device are simplified, and requirements for the image display device are lowered.
As described above, the video display device required in the system of the present invention requires much lower specifications than the video display device used in the conventional multi-vision system, so that cost can be reduced when configuring a multi-vision system. In addition, when a plurality of image display devices are required to form an image output system on a large scale, further cost reduction can be achieved.
Regarding the above-described predetermined rule, FIG. 7 shows a method in which images reconstructed in a system for outputting an image according to an embodiment of the present invention are transmitted to each image display device.
In FIG. 7, image data transmitted to the receiving subsystem 200 is image data reconstructed in advance by the transmission subsystem 100, and includes an upper left image (images 1 and 1), an image at the upper right (images 2 and 2), The lower right image (videos 4 and 4) and the lower left image (images 3 and 3) are transmitted to the receiving subsystem 200 in this order.
In the method shown in FIG. 7, each video display device of the receiving subsystem 200 receives and stores only the number of pixels of a resolution capable of outputting the received video data, and additionally received video data For the next connected video display device.
When the first image 1 is first transmitted to the first image display device 210 from the image display devices set according to these rules, the first image display device 210 displays as many images as the number of pixels it can output. The data is stored in an image storage unit (Fig. 7a), and all additionally received image data 2 to 4 are transferred to the second image display device 220 (Fig. 7b).
For example, as shown in FIG. 4, if the resolution of the first image display device is 720 X 480, the first image display device 210 first stores image data having a number of 345,600 pixels among the received image data. All additional image data stored in the unit and subsequently received may be transmitted to the second image display device 220.
Here, since each of the images 1 to 4 has been scaled to be output from each image display device, the first image 1 is data having the same number of pixels as the resolution that the first image display device 210 can output. And, image 2 (2) is data having the same number of pixels as the resolution that can be output by the second image display device 220, and image 3 (3) is the data of the third image display device 230 The data has the same number of pixels as the resolution, and the fourth image 4 is data having the same number of pixels as the resolution that the fourth image display device 240 can output.
The second image display device 220 receives the second image 2 from the first image display device, and stores the second image 2, which is the number of pixels that can be output, in the image storage unit. And (b), all the additionally received image data are transmitted to the fourth image display device 240 (Fig. 7C).
The fourth image display device 240 receives the fourth image 4 from the second image display device according to the order of the reconstructed image data, and the fourth image 4 is image data having a resolution that can be output by itself. ) Is stored in the image storage unit (FIG. 7C), and all additionally received image data are transferred to the third video display device 230 (FIG. 7D).
The third image display device 230 receives the third image 3 from the fourth image display device according to the order of the reconstructed image data, and the third image ( 3) is stored in the image storage unit (Fig. 7d).
When all images are transmitted to the receiving subsystem 200, the transmitting subsystem 100 transmits a synchronization signal to the receiving subsystem 200. Here, the synchronization signal may be a vsync signal or other synchronization signals such as hsync and clock signals.
When a synchronization signal is received from the receiving subsystem 200, all of the video display devices operate to simultaneously output the stored video data.
8 illustrates a case in which a rule different from the above-described predetermined rule is applied, and illustrates a method in which images reconstructed in a system for outputting an image according to another embodiment of the present invention are transmitted to each image display device. Shows.
In FIG. 8, the image data transmitted to the receiving subsystem 200 is image data reconstructed in advance by the transmission subsystem 100, and the lower left image (images 3 and 3) and the lower right image (images 4 and 4). ), the upper right image (images 2 and 2), and the upper left image (images 1 and 1) are transmitted to the receiving subsystem 200 in this order.
In the method shown in FIG. 8, each video display device of the receiving subsystem 200 receives and stores only the size of the number of pixels that the video display device can output, and additionally receives the video data. Then, the image data previously stored in the image storage unit is transferred to the next connected image display device, and the operation of storing additionally received image data in the image storage unit as much as the resolution size that the corresponding image display device can output is repeated. Is configured to
Here, in addition to transferring the previously stored image data to the next image display device, the image storage unit may also perform an operation of deleting the previously stored image data. If the previously stored image data is not deleted, additionally received image data may be overwritten and stored in the image storage unit.
In the video display devices set according to these rules, the third image 3 is first transmitted to the first video display device 210, and the first video display device 210 is the number of pixels of the resolution that can be output. When image 3 (3), which is the image data of, is stored in the image storage unit (Fig. 8 a), and when image 4 (4) is additionally received, the previously stored image 3 (3) is transferred to the second image display device. The image 4, which is transmitted to 220, and is additionally received, is stored in the image storage unit of the first image display device 210 (FIG. 8B).
After image 4 (4) is stored in the image storage unit of the first image display device 210, when the second image (2) is additionally received, the first image display device 210 is stored in the image storage unit. The image No. 4 is transferred to the second image display device 220, and the additionally received image No. 2 is stored in the image storage unit of the first image display device 210 (Fig. 8C). .
After the second image 4 is stored in the image storage unit of the first image display device 210, when an additional image 1 is received, the first image display device 210 is stored in the image storage unit 2 The image No. 2 is transferred to the second image display device 220, and the additionally received image No. 1 is stored in the image storage unit of the first image display device 210 (Fig. 8D). .
Eventually, image 1 (1) is in the storage unit of the first image display device 210, image 2 (2) is in the storage unit of the second image display device 220, and image 3 (3) is In the storage unit of the third image display device 230, the fourth image 4 is stored in the storage unit of the fourth image display device 210.
When all images are transmitted to the receiving subsystem 200, the transmitting subsystem 100 transmits a synchronization signal to the receiving subsystem 200. Here, the synchronization signal may be a vsync signal or other synchronization signals such as hsync and clock signals.
When a synchronization signal is received from the receiving subsystem 200, all of the video display devices operate to simultaneously output the stored video data.
9 is a flowchart illustrating a method of transmitting image data to each image display device in a system for outputting an image according to an embodiment of the present invention.
In FIG. 9, the steps performed in the transmission subsystem 100 are displayed in the box of S1100, the steps performed in the first video display device 210 are displayed in the box of S1200, and the second video display device 220 The steps performed are displayed in the box of S1300, and the steps performed by the last video display device are displayed in the box of S1400.
The transmission subsystem 100 scales the image to be output according to the image output capability of the reception subsystem 200 on the original image data to be output from the plurality of image display devices (S1110). The scaled image data is divided according to the number of image display devices to which the image is output (S1120). The order of the divided image data is reconfigured to be transmitted to an appropriate image display device according to the order of the connected image display devices (S1130). The reconstructed image data is transmitted to the receiving subsystem 200.
The first image marking device 210 of the receiving subsystem 200 receives image data from the transmitting subsystem 100 (S1210). The received image data is stored in the image storage unit 215 of the first image display device 210. The first image display device calculates the number of pixels of the stored image data and determines whether the image data is stored as many as the number of pixels of the resolution of the first image display device (S1230). When the image data is stored as many pixels as the first image display device can output, the first image display device transmits the additionally transmitted image data to the second image display device (S1240).
The second video display device 220 receives image data from the first video display device 210 (S1310). The second image display device 220 stores the received image data in the image storage unit (S1320), calculates the size of the stored image data, and determines whether the data is stored as many as the number of pixels that the second image display device can output. It is determined (S1330). When the image data is stored as much as the resolution capable of being output by the second image display device, the second image display device transmits the additionally transmitted image data to the next connected image display device (S1340).
These operations are performed in the same manner in the connected video display devices, so that each video display device stores image data to be output by itself.
Finally, the connected video display device receives image data from the video display device connected immediately before storing it in an image storage unit (S1410). The last video display device determines whether or not the image data has been stored as much as an outputable size (S1420), and waits to receive a synchronization signal when the image data is stored enough to be output by the last video display device.
When all of the image data is transmitted to the receiving subsystem 200, the transmitting subsystem 100 transmits the synchronization signal to the receiving subsystem 200, and the video display devices receiving the synchronization signal are images stored in each video display device. Data can be output simultaneously.
10 is a flowchart illustrating a method of transmitting image data to each image display device in a system for outputting an image according to another exemplary embodiment of the present invention.
In FIG. 10, the steps performed in the transmission subsystem 100 are displayed in the box of S2100, the steps performed in the first video display device 210 are displayed in the box of S2200, and the second video display device 220 The steps performed are displayed in the box of S2300, and the steps performed by the last video display device are displayed in the box of S2400.
The transmission subsystem 100 scales an image to be output according to the image output capability of the reception subsystem 200 on the original image data to be output from the plurality of image display devices (S2110). The scaled image data is divided according to the number of image display devices to which the image is output (S2120). The order of the divided image data is reconfigured to be transmitted to a suitable image display device according to the order of the connected image display devices (S2130). The reconstructed image data is transmitted to the receiving subsystem 200.
The first video labeling device 210 of the receiving subsystem 200 receives image data from the transmitting subsystem 100 (S2210). The received image data is stored in the image storage unit 215 of the first image display device 210 (S2220). The first image display device calculates the size of the image data to be stored and determines whether image data corresponding to a resolution capable of being output by the first image display device is stored (S2230). When the image data is stored as much as the resolution capable of being output by the first image display device, the first image display device 210 transfers the previously stored image data to the second image display device 220, and pre-stored in the image storage unit. The image data is deleted (S2240). In addition, the operation of receiving additionally transmitted image data and storing it in the image storage unit is repeated. In this embodiment, after deleting the image data previously stored in the image storage unit, the added image data is stored in the image storage unit, but it is possible to overwrite the added image data in the image storage unit without deleting the previously stored image data. Do.
The second video display device 220 receives image data from the first video display device 210 (S2310). The second image display device 220 stores the received image data in an image storage unit (S2320), calculates the size of the stored image data, and stores image data of a resolution that can be output by the second image display device. It is determined whether or not (S2330). When the image data is stored as many as the number of pixels that the second image display device can output, the second image display device 210 transfers the previously stored image data to the third image display device 230, and the previously stored image data is It is deleted (S2340). In addition, the operation of receiving additionally transmitted image data and storing it in the image storage unit is repeated.
These operations are performed in the same manner in the connected video display devices, so that each video display device stores image data to be output by itself.
Finally, the connected video display device receives image data from the video display device connected immediately before storing it in the image storage unit (S2410). The last image display device may determine whether the image data is stored as much as an output possible resolution (S2420), and if the image data is stored as much as the last image display device outputs, may wait to receive a synchronization signal.
All of the image data from the transmission subsystem 100 has been transferred to the reception subsystem 200, the transmission subsystem 100 transmits a synchronization signal to the reception subsystem 200, and the video display devices receiving the synchronization signal are each The video data stored in the video display device of can be simultaneously output.
The transmission subsystem 100 may transmit such a synchronization signal to the reception subsystem 200 whenever each frame of an image to be output from the video display devices is stored in the video display devices 210, 220, 230, and 240. have.
The image output system according to the embodiments of the present invention is not limited to the configuration and method of the embodiments described as described above, but selectively combining all or part of each of the embodiments so that various modifications can be made. It can also be configured.
In addition, although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Of course, various modifications can be implemented by those with ordinary knowledge.

100: transmission subsystem 110: image scaler
120: image reconstruction unit 130: image transmission unit
200: receiving subsystem 210: first video display device
211: image receiving unit 213: pixel counter
215: image storage unit 217: image output unit
219: image transmission unit 220: second image display device
230: third video display device 240: fourth video display device

Claims (15)

A system for outputting an image to a plurality of image display devices,
A transmission subsystem that processes and transmits the image data, and a reception subsystem that receives and outputs the processed image data from the transmission subsystem,
The receiving subsystem includes a plurality of video display devices,
The plurality of video display devices are sequentially connected,
The transmitting subsystem scales the image data based on the image output capability of the receiving subsystem, and divides the scaled image data into a plurality of blocks representing portions to be output from each of the plurality of image display devices, Reconstructing an order of blocks of divided image data based on an order in which the image display devices are connected, and transmitting the reconstructed blocks of image data to the receiving subsystem according to the reconstructed order,
Each video display device of the receiving subsystem is configured to store the received video data in the video storage unit of the video display device according to a predetermined rule or to transmit the received video data to the video display device after being connected to the video display device,
Each video display device of the receiving subsystem includes a pixel counter that counts the number of pixels of an image represented by the received image data,
Each video display device of the receiving subsystem,
By using the pixel counter, the image data representing the number of pixels corresponding to the resolution of the corresponding video display device is received and stored in the image storage unit of the video display device. When additional video data is received, the video display device Configured to transfer the additional image data to the next video display device connected to,
A system for outputting video.
delete The method of claim 1,
The image output capability of the receiving subsystem is determined based on resolution information of each video display device of the receiving subsystem,
The transmission subsystem scales the image data based on the resolution information and the number of image display devices to output the image data,
A system for outputting video.
The method of claim 1,
The image output capability of the receiving subsystem is a sum of resolutions of the plurality of image display devices, and each block of the divided image data has the same resolution as the resolution of the image display device to which the block of image data is to be output,
A system for outputting video.
delete A system for outputting an image to a plurality of image display devices,
A transmission subsystem that processes and transmits the image data, and a reception subsystem that receives and outputs the processed image data from the transmission subsystem,
The receiving subsystem includes a plurality of video display devices,
The plurality of video display devices are sequentially connected,
The transmitting subsystem scales the image data based on the image output capability of the receiving subsystem, and divides the scaled image data into a plurality of blocks representing portions to be output from each of the plurality of image display devices, Reconstructing an order of blocks of divided image data based on an order in which the image display devices are connected, and transmitting the reconstructed blocks of image data to the receiving subsystem according to the reconstructed order,
Each video display device of the receiving subsystem is configured to store the received video data in the video storage unit of the video display device according to a predetermined rule or to transmit the received video data to the video display device after being connected to the video display device,
Each video display device of the receiving subsystem includes a pixel counter that counts the number of pixels of an image represented by the received image data,
Each video display device of the receiving subsystem,
Using the pixel counter, the image data representing the number of pixels corresponding to the resolution of the corresponding image display device is received and stored in the image storage unit of the corresponding image display device, and when additional image data is received, the image storage unit The image data previously stored in the video display device is transferred to the video display device after being connected to the video display device, and the video data representing the number of pixels corresponding to the resolution of the video display device among additionally received video data is transferred to the video display device. It is configured to repeat the operation of storing in the image storage unit,
A system for outputting video.
The method according to any one of claims 1, 3, 4, and 6,
The transmission subsystem is further configured to transmit a synchronization signal after all blocks of the reconstructed image data have been transmitted to the image display devices,
Each video display device of the receiving subsystem is further configured to simultaneously output video data stored in an image storage unit of each video display device upon receiving the synchronization signal,
A system for outputting video.
delete A method for outputting an image to a plurality of image display devices, performed in an image output system including a transmission subsystem and a reception subsystem including a plurality of image display devices,
Scaling the image data in the transmitting subsystem to match the image output capability of the receiving subsystem;
Dividing the scaled image data into a plurality of blocks representing a portion to be output from each of the plurality of image display devices in the transmission subsystem;
Reconstructing an order of blocks of the divided image data in the transmission subsystem based on an order in which the image display devices are connected;
Transmitting blocks of the image data reconstructed by the transmitting subsystem to the receiving subsystem according to the reconstructed order;
Receiving blocks of the reconstructed image data in the receiving subsystem; And
Storing the video data received from each video display device of the receiving subsystem in the video storage unit of the video display device according to a predetermined rule or transmitting the video data to the video display device after being connected to the video display device,
Between the receiving step and the transmitting step,
Counting the number of pixels of an image represented by image data received from each image display device in each image display device of the receiving subsystem,
The transferring step,
Receiving image data representing the number of pixels corresponding to the resolution of the corresponding image display device from each image display device of the receiving subsystem and storing the image data in an image storage unit of the image display device; And
When additional image data is received from each image display device, the step of transmitting the additional image data to a next image display device connected to the corresponding image display device,
Method for outputting video.
delete The method of claim 9,
The image output capability of the receiving subsystem is determined based on resolution information of each video display device of the receiving subsystem,
The scaling comprises scaling the image data based on the resolution information and the number of image display devices to output the image data,
Method for outputting video.
The method of claim 9,
The image output capability of the receiving subsystem is the sum of the resolutions of the plurality of image display devices, and each of the blocks of the divided image data has a resolution equal to the resolution of the image display device to which the block of image data is to be output,
Method for outputting video.
delete A method for outputting an image to a plurality of image display devices, performed in an image output system including a transmission subsystem and a reception subsystem including a plurality of image display devices,
Scaling the image data in the transmitting subsystem to match the image output capability of the receiving subsystem;
Dividing the scaled image data into a plurality of blocks representing a portion to be output from each of the plurality of image display devices in the transmission subsystem;
Reconstructing an order of blocks of the divided image data in the transmission subsystem based on an order in which the image display devices are connected;
Transmitting blocks of the image data reconstructed by the transmitting subsystem to the receiving subsystem according to the reconstructed order;
Receiving blocks of the reconstructed image data in the receiving subsystem; And
Storing the video data received from each video display device of the receiving subsystem in the video storage unit of the video display device according to a predetermined rule or transmitting the video data to the video display device after being connected to the video display device,
Between the receiving step and the transmitting step,
Counting the number of pixels of an image represented by image data received from each image display device in each image display device of the receiving subsystem,
The transferring step,
Receiving image data representing the number of pixels corresponding to the resolution of the corresponding image display device from each image display device of the receiving subsystem and storing the image data in an image storage unit of the image display device; And
When additional image data is received from each image display device, the image data previously stored in the image storage unit is transferred to the next image display device after being connected to the image display device, and among the additional image data, the resolution of the image display device is appropriate. Comprising the step of storing image data representing the number of pixels in the image storage unit of the image display device,
Method for outputting video.
The method according to any one of claims 9, 11, 12, and 14,
Transmitting a synchronization signal from the transmitting subsystem to the receiving subsystem after all blocks of the reconstructed image data have been transmitted from the transmitting subsystem to the receiving subsystem; And
When each video display device of the receiving subsystem receives the synchronization signal, further comprising simultaneously outputting video data stored in an image storage unit of each video display device,
Method for outputting video.

Images