KR20200141203A - Apparatus and method for providing video contents - Google Patents

Abstract

The present invention relates to a device for providing image content and a method thereof. According to the present invention, a control method of an image content providing server comprises the steps of: dividing each image frame of the image content into divided images for each preset divided area; grouping the divided images of each image frame divided in the above step by corresponding divided area to generate individual image streams; and transmitting the individual image stream generated in the above step to an image playing device.

Description

Apparatus and method for providing video content {APPARATUS AND METHOD FOR PROVIDING VIDEO CONTENTS}

The present invention relates to an apparatus and method for providing video content, and more particularly, to an apparatus and method for providing at least part of a specific video content at the request of a viewer.

With the development of electronic communication technology, a high-definition video providing service is widely used unlike the existing one.

In particular, in recent years, it is possible to provide an ultra-high-definition video such as a 4K video or an 8K video to a video reproducing terminal operated by a viewer.

However, in order to send 4K to 8K ultra-high-definition video to the viewer's terminal, a transmission bandwidth of approximately 80 Mbps to 120 Mbps is required, but it was not easy to secure such a large rental width in the conventional wireless communication service. Attempts are being made to provide ultra-high quality images.

However, no matter how much the 5G communication era has arrived, providing ultra-high-definition video to each mobile communication user is a significant burden on wireless communication network operation.

In particular, in the case of a wireless communication terminal, it is possible to enlarge a specific part of the image received through touch manipulation (for example, by expanding only one of the singers they like) to watch, regardless of the various choices of these individuals. Providing the same ultra-high-definition video can be said to be a significant inefficient processing related to the operation of the communication network.

Therefore, it is time to need a plan to increase the operating efficiency of a wireless communication network in connection with providing ultra-high-definition images.

Registered Patent No. 10-1536140

The present invention was devised to meet the above-described conventional needs, and its object is an apparatus for providing video content that can maximize wireless communication network efficiency while meeting various needs of users in providing a large-capacity ultra-high definition video service And to provide a method.

In order to achieve the above object, a video content providing server according to the present invention includes: an video division unit for dividing each video frame of video content into divided images for each divided area; An image stream generator configured to generate a separate image stream by grouping the divided images of each image frame divided by the image segmentation unit by corresponding divided regions; And a transmission unit for transmitting the individual video stream generated by the video stream generation unit to the video reproducing apparatus.

In addition, in order to achieve the above object, a method of controlling a video content providing server according to the present invention includes the steps of: dividing each video frame of video content into divided images for each preset divided area; Grouping the divided images of each image frame divided in the step by corresponding divided regions to generate individual video streams; And transmitting the individual video stream generated in the above step to the video reproducing apparatus.

As described above, according to the present invention, the high-definition image is divided into predetermined segmented images and transmitted, thereby preventing excessive occurrence of network traffic.

Particularly, when a viewer enlarges a portion of the image content or moves it to an adjacent area in the enlarged state, the image moves naturally, thereby minimizing viewer discomfort.

1 is a schematic configuration diagram of an entire system including a content providing server according to an embodiment of the present invention,
2 is a functional block diagram of the content providing server of FIG. 1;
3 is a diagram showing a state in which each video frame of video content is divided into preset regions,
FIG. 4 is a diagram illustrating a process of being grouped for each divided region of FIG. 3 to generate an individual video stream;
5 is a diagram showing an example of each individual video stream,
6 is a diagram showing a state in which video content is divided into various sizes,
7 is a control flowchart of an entire system including a content providing server according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, each embodiment according to the present invention is only one example for aiding understanding of the present invention, and the present invention is not limited to these embodiments. In particular, the present invention may be configured with a combination of at least one or more of individual configurations, individual functions, or individual steps included in each embodiment.

In particular, for convenience, some claims in the claims include alphabets such as'(a)', but these alphabets do not prescribe the order of each step.

In addition, each signal mentioned in each embodiment according to the present invention may mean one signal transmitted by one connection or the like, but may also mean a series of signal groups transmitted for the purpose of performing a specific function to be described later. . That is, in each embodiment, a plurality of signals transmitted at a predetermined time interval or transmitted after receiving a response signal from a counterpart device may be expressed as one signal name for convenience.

A schematic configuration of the entire communication system including the content providing server 100 according to an embodiment of the present invention is as shown in FIG. 1.

As shown in the figure, the entire communication system includes a content reproducing apparatus 200 and a content providing server 100.

Here, the content playback device 200 receives and plays video content from the content providing server 100, and may be a portable wireless communication terminal such as a smartphone or a wired communication device such as a computer provided in the home. In describing an example, the content playback device 200 is an example of a wireless communication terminal such as a smart phone or PDA (Personal Digital Assistants).

Therefore, the content playback device 200 must include a function to play the video content received from the content providing server 100, and in particular, the content playback device 200 expands a portion of the received video according to the viewer's selection. A user interface for doing this may be provided.

For example, the content reproducing apparatus 200 may enlarge and reproduce a specific area of the currently playing video content based on a specific location according to a viewer's touch manipulation.

In this case, the content reproducing apparatus 200 may transmit a content request signal corresponding to the enlargement request of the viewer to the content providing server 100.

That is, the content reproducing apparatus 200 may transmit a content request signal including predetermined information according to the manipulation to the content providing server 100 whenever a viewer's manipulation is detected. When the specific area is enlarged to check the specific area in detail, the content reproducing apparatus 200 may transmit a content request signal including information corresponding to the corresponding enlarged area to the content providing server 100.

Here, the information corresponding to the above-described enlarged area may be regarded as an example of viewing area information of video content that the viewer views using the content reproducing apparatus 200.

The viewing area information may be referred to as information indicating a viewing area that the viewer is actually viewing in the video content. For example, when the resolution of the video content is greater than the resolution supported by the content playback device 200, the content playback device 200 ), the video content cannot be displayed on one screen. In this case, the viewer can move the video content up, down, left, right, etc. through touch manipulation. The information indicating the present area is the viewing area information.

This is a situation that occurs even when the viewer enlarges part of the video content as described above.

Meanwhile, the content providing server 100 provides video content according to the request of the content reproducing device 200, and in particular, may provide video content through a streaming method.

In addition, the content providing server 100 may divide the video content according to a preset algorithm and transmit only a portion of the divided (i.e., individual video stream) to the content playback device 200, in which case the content providing server 100 Video content or individual video streams to be transmitted may be selected according to the request of the playback device 200.

An example of a specific functional block of the content providing server 100 is as shown in FIG. 2.

As shown in the figure, the content providing server 100 includes an image segmentation unit 110, an image stream generation unit 120, a transmission unit 130, a request receiving unit 140, and a storage unit 150. do.

First, the storage unit 150 not only stores applications, data, and settings required for the operation of the content providing server 100, but also stores data or information generated during the operation of the content providing server 100 or received from the outside. It performs the function of saving.

In particular, the storage unit 150 may temporarily store video content provided to the content reproducing apparatus 200 as well as each video stream or individual video stream generated by the video stream generation unit 120 to be described later.

The image segmentation unit 110 performs a function of dividing each image frame of the image content into divided images for each divided region.

Such an example is well shown in FIG. 3, but first, FIGS. 3(a) to 3(c) show each image frame of video content. For convenience, FIG. 3(a) is a first video frame, and FIG. 3(b) is a 2 video frames, and Fig. 3(c) is referred to as a third video frame.

That is, a video is made by a combination of each video frame. For example, 30 frame video content means that there are 30 video frames per second, and 60 frame video content means that there are 60 video frames per second. It means there is a frame.

The fact that the video content consists of a plurality of video frames corresponds to a known technology, and thus a more detailed description thereof will be omitted.

Meanwhile, referring to FIG. 3, each image frame is divided into four divided regions. The image division unit 110 divides each image frame into divided regions, and then extracts a divided image included in the divided regions. Perform.

That is, four divided images p1-1, p1-2, p1-3, and p1-4 are generated from the first image frame of FIG. 3(a), that is, the second image frame of FIG. 3(b) Four divided images (p2-1, p2-2, p2-3, p2-4) are generated from the image frame, and four divided images (p3-1, p3-2, and p3-2) are generated from the third image frame of FIG. 3(c). p3-3, p3-4) is generated.

This process may be performed in the same manner in each subsequent image frame.

The request receiving unit 140 performs a function of receiving a content request signal including viewing area information from the video reproducing device, wherein the viewing area information is an image currently being viewed by a viewer of the content reproducing apparatus 200 as described above. It is information about the area of the content.

The viewing area information may include viewing area size information and viewing area identification information, where the viewing area size information is information indicating the size of an area that the viewer is watching among video contents, and the viewing area location information is the viewer of the video content. This is information indicating a location (for example, coordinates) on the video content being watched.

The video stream generation unit 120 performs a function of grouping the divided images of each video frame divided by the video division unit 110 by corresponding divided regions to generate individual video streams.

That is, the video stream generation unit 120 generates one individual video stream by collecting video images in the same divided area from each filter image frame.

For example, referring to FIG. 3, the video stream generator 120 includes a split image p1-1 of a first split area of a first video frame and a split image p2- of a first split area of a second video frame. 1) The divided image p3-1 of the first divided area of the third video frame is grouped to generate a separate video stream (ie, a first individual video stream) including each of the divided images.

This is also the case for other divided areas.

That is, the video stream generator 120 includes a split image p1-2 of the second split area of the first video frame, a split image p2-2 of the second split area of the second video frame, and a third video frame. By grouping the divided image p3-2 of the second divided area of the, it is possible to generate an individual video stream (ie, a second individual video stream) including each of the divided images. Since the third and fourth divided regions are the same, redundant descriptions are omitted.

As described above, FIG. 4 is shown in FIG. 4 to help understand a process in which the video stream generator 120 groups the divided images of each video frame divided by the video splitter 110 by corresponding divided regions to generate individual video streams. Shown.

Referring to FIG. 4, assuming that each frame of video content is sequentially progressing, each of the video frames is divided into four divided regions, and one individual video stream in which divided images of the same divided region are sequentially arranged is generated. It can be.

In this case, it can be said that 8K video content is divided into four 4K video content.

In this way, the number of divided regions to divide each image frame of one image content may be based on preset information or a request signal received from the content reproducing apparatus 200.

Meanwhile, the transmission unit 130 performs a function of transmitting the individual video stream generated by the video stream generation unit 120 to the video reproducing apparatus.

In this case, the transmission unit 130 may transmit an individual video stream corresponding to the viewing area information included in the content request signal of the video reproducing apparatus to the video reproducing apparatus.

For example, if a viewer wants to enlarge and view a location corresponding to the first divided area in FIG. 4 while viewing video content on the full screen, such a touch manipulation request signal of the viewer is received by the content providing server 100 In this case, according to the request, the transmission unit 130 selects only the first individual video stream and transmits it to the content playback device 200 in a state where the first individual video stream and the second individual video stream exist as shown in FIG. 4. It can be.

That is, when the viewer does not enlarge the video content, the transmission unit 130 transmits a video stream including the entire video content to the content reproducing apparatus 200, When the viewing of the enlarged screen is detected, only the divided first individual video stream may be selected and transmitted to the content reproducing apparatus 200 instead of the entire video stream.

Here, as an example, the entire video content is transmitted to the content playback device 200 as an undivided video stream, but the entire video content is also content after each divided individual video stream is transmitted to the content playback device 200. It goes without saying that each individual video stream may be combined into entire video content by the playback device 200.

In addition, the transmission unit 130 transmits the first individual video stream (that is, the stream in which the first divided images corresponding to the first divided regions are grouped according to the order of each video frame) to the video reproducing apparatus. 2 When a content request signal including viewing area information corresponding to the divided area is received by the request receiving unit 140, a second individual video stream (that is, a second divided image corresponding to the second divided area is included in each video frame). The grouped stream) may be selected in order and transmitted to the video reproducing apparatus.

For example, if a viewer is viewing an image corresponding to the first divided area among video contents through screen enlargement manipulation, the transmission unit 130 may be configured to receive a first individual image corresponding to the first divided area as shown in FIG. 5(a). The video stream is transmitted to the content reproducing apparatus 200. In this case, if the viewer tries to view the video corresponding to the second divided area of the video content through screen movement operation again, the transmission unit 130 is shown in FIG. 5(b). The second individual video stream corresponding to the same second divided region is transmitted to the content reproducing apparatus 200.

That is, if the viewer enlarges and views the location corresponding to the first divided area, the transmission unit 130 does not need to transmit the entire video content, so as shown in FIG. 5(a), the first individual video stream, that is, Split images p1-1, p1-2, p1-3, p1-4, p1-5, etc. are transmitted to the content playback apparatus 200 in succession, and if the split image p1 of FIG. 5(a) At the time when -2 is transmitted to the content playback device 200, a movement request signal from the content playback device 200 to a location corresponding to the second divided area according to the viewer's manipulation (that is, the viewer corresponds to the second divided area. When a request signal generated when an enlarged view of the video content is desired is received, the transmission unit 130 selects a second individual video stream such as p2-3, p2-4, and p2-5, and 200).

In this case, referring to FIG. 5(b), it can be seen that the second individual video stream includes the second split image extracted from the video frame corresponding to the sequence number next to the video frame of the first split image transmitted to the current video playback device. . That is, in Fig. 5(b), it can be seen that p1-1 and p1-2 are transmitted from p2-3, and this is the last frame transmitted through the first individual video stream (i.e., the second video frame ), transmitting the second individual video stream to the content reproducing apparatus 200 starting from the divided image of the second divided region included in the next frame (ie, the third video frame).

Meanwhile, as described above, the content request signal may include viewing area size information and viewing area location information as viewing area information. After calculating the size of the divided area corresponding to the viewing area size information, An individual video stream corresponding to both the calculated size of the divided area and the location information of the viewing area may be selected and transmitted to the video reproducing apparatus.

For example, the image segmentation unit 110 continuously generates individual image streams corresponding to each segmented area, and the transmission unit 130 may provide any one or a plurality of individual images according to the request of the content playback device 200. A stream may be selected and transmitted to the content playback device 200, and at this time, the viewing area size information and/or viewing area location included in the content request signal of the content playback device 200 is the selection criterion for the individual video stream to be transmitted. It is information.

As an example, a 4K individual video stream is generated based on the divided image divided into four as shown in FIG. 6(a) by the video division unit 110 from the entire 8K video content, and the video division unit 110 in FIG. 6 Assuming that 2K individual video streams divided into 16 as shown in (b) are being generated, the transmission unit 130 refers to the size and position of the viewing image currently being enlarged and viewed by the viewer as shown in FIG. 6(a). At least one of the 4K individual video streams or at least one of the 2K individual video streams shown in FIG. 6(b) can be transmitted to the content reproducing apparatus 200.

7 is a diagram illustrating a signal and control flow between a content providing server 100 and a content reproducing apparatus 200 communicating with the content providing server 100 according to an embodiment of the present invention.

In response to the video content request from the content reproducing apparatus 200 (step S1), the content providing server 100 extracts pre-stored video content and transmits it to the content reproducing apparatus 200 (step S3). In this case, the content providing server 100 may transmit a video stream for the entire video content to the content reproducing apparatus 200.

Accordingly, the content reproducing apparatus 200 plays the video content received from the content providing server 100 (step S4).

Subsequently, when the viewer detects a screen enlargement operation on the video content being viewed (step S5), the content playback device 200 performs an enlargement process (step S7), and the enlarged location information (eg, coordinates on the video content) Is transmitted to the content providing server 100 (step S9).

The content providing server 100 selects an individual video stream corresponding to the location information received from the content playback device 200 (step S11) and transmits it to the content playback device 200 (step S13).

For example, if the enlarged location is a location corresponding to the second divided area, the content providing server 100 transmits a second individual video stream corresponding to the second divided area to the content reproducing apparatus 200.

Accordingly, the content reproducing apparatus 200 reproduces and displays the second individual video stream received from the content providing server 100 (step S15).

Subsequently, when the viewer detects the movement of the viewing area (step S17), the content reproducing apparatus 200 transmits the moved coordinates to the content providing server 100 (step S19).

The content providing server 100 selects an individual video stream based on the moving coordinates received from the content playback device 200 (step S21) and transmits it to the content playback device 200 (step S23). For example, a viewer When the viewing screen is moved to a location corresponding to the 3 divided area, the content providing server 100 transmits a third individual video stream corresponding to the third divided area to the content reproducing apparatus 200.

Accordingly, the content reproducing apparatus 200 reproduces the third individual video stream received from the content providing server 100 (step S25), and eventually, the viewer can view the video corresponding to the third divided region.

In the above-described embodiments, on the premise that the content providing server 100 generates each individual video stream based on the video content, regardless of the request of the viewer, it is determined according to the request of the viewer (ie, viewing area information described above). Although it has been described as an example that at least one of the plurality of individual video streams to be generated is selectively provided, it is of course possible to dynamically generate a necessary individual video stream only when requested by a viewer.

For example, while the content providing server 100 is providing the entire video content to the content playback device 100, a request signal including viewing area information according to the expansion of a user's specific viewing area is received from the content playback device 100 Upon reception, it is also possible to generate an individual video stream according to the viewing area information.

That is, the content providing server 100 may determine the location of the divided area corresponding to the individual content stream to be transmitted, as well as the size of the divided area, according to the viewer's screen enlargement position and the degree thereof.

For example, when a viewer wants to view a viewing video corresponding to 8K video content by slightly expanding it, the content providing server 100 may divide the video content into 4K video and generate each individual video stream. In the case of a larger enlarged view of the video to be viewed, the content providing server 100 may generate a separate video stream after dividing the video content into 2K video by 16.

This processing is of greater significance when the content reproducing apparatus 200 and the content providing server 100 have a 1:1 relationship.

Meanwhile, it goes without saying that the process of performing each of the above-described embodiments may be performed by a program or application stored in a predetermined recording medium (eg, computer-readable). Here, the recording medium includes all of an electronic recording medium such as a random access memory (RAM), a magnetic recording medium such as a hard disk, and an optical recording medium such as a compact disk (CD).

In this case, the program stored in the recording medium may be executed on hardware such as a computer or a smart phone to perform each of the above-described embodiments. In particular, at least one of the functional blocks of the content providing server according to the present invention described above may be implemented by such a program or application.

In addition, the present invention is not limited to the specific embodiments described above, but can be implemented by various modifications and modifications without departing from the gist of the present invention. It will be apparent that such modifications and modifications are included in the present invention if they fall within the appended claims.

100: content providing server 200: content playback device
110: image segmentation unit 120: image stream generation unit
130: transmitting unit 140: request receiving unit
150: storage unit

Claims (10)

(a) dividing each video frame of video content into divided images for each divided area;
(b) grouping the divided images of each video frame divided in step (a) by corresponding divided regions to generate individual video streams;
(c) transmitting the individual video stream generated in step (b) to a video reproducing apparatus. The method of claim 1,
(d) receiving a content request signal including viewing area information from the video reproducing apparatus,
In the step (c), an individual video stream corresponding to the viewing area information included in the content request signal of the video reproducing apparatus is transmitted to the video reproducing apparatus. The method of claim 2,
In the step (c), a first separate video stream in which a first divided image corresponding to a predetermined first divided area is grouped according to the order of each video frame is transmitted to the video reproducing apparatus. When a content request signal including viewing area information corresponding to the second divided area of is received, a second individual video stream in which a second divided image corresponding to the second divided area is grouped according to the order of each video frame is transmitted to the video. Transfer to the playback device,
The control method of a video content providing server, characterized in that the second individual video stream includes a second split image extracted from a video frame corresponding to a sequence number following the video frame of the first split image currently transmitted to the video playback device. . The method of claim 2,
The viewing area information in step (d) includes viewing area size information and viewing area location information,
In the step (c), after calculating the size of the divided area corresponding to the viewing area size information, the calculated size of the divided area and the individual video stream corresponding to the viewing area location information are transmitted to the video reproducing apparatus. Control method of a video content providing server, characterized in that. A computer-readable recording medium storing a program for executing the method of any one of claims 1 to 4. An application program stored in a computer-readable recording medium to execute the method of any one of claims 1 to 4 in combination with hardware. An image dividing unit for dividing each image frame of the image content into divided images for each divided area;
An image stream generator configured to generate a separate image stream by grouping the divided images of each image frame divided by the image segmentation unit by corresponding divided regions;
And a transmission unit for transmitting the individual video stream generated by the video stream generation unit to a video playback device. The method of claim 7,
Further comprising a request receiving unit for receiving a content request signal including viewing area information from the video playback device,
And the transmission unit transmits an individual video stream corresponding to the viewing area information included in the content request signal of the video reproducing apparatus to the video reproducing apparatus. The method of claim 8,
The transmission unit transmits a first individual video stream in which a first divided image corresponding to a predetermined first divided area is grouped according to an order of each video frame to the video reproducing apparatus, while a second sub-region from the video reproducing apparatus When a content request signal including viewing area information corresponding to is received by the request receiving unit, a second individual video stream in which a second divided image corresponding to the second divided area is grouped according to the order of each video frame is transmitted to the video. Transfer to the playback device,
Wherein the second individual video stream includes a second split image extracted from a video frame corresponding to a sequence number next to the video frame of the first split image currently transmitted to the video reproducing apparatus. The method of claim 8,
The content request signal includes viewing area size information and viewing area location information as viewing area information,
The transmission unit calculates the size of the divided area corresponding to the viewing area size information, selects an individual video stream corresponding to the calculated size of the divided area and the viewing area location information, and transmits it to the video reproducing apparatus. Video content providing server characterized by.

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