WO2017171242A1 - Method and apparatus for implementing translucent menu screen image in device capable of connecting hd set-top box to uhd tv - Google Patents

Abstract

Provided is a method capable of using a conventional HD or full-HD set-top box, of which UHD broadcast processing is impossible, by connecting the set-top box to a UHD TV, and displaying a translucent menu screen image. The method according to the present invention comprises: an image reception step of receiving an OSD image and transparency information from an HD set-top box through a first HDMI interface and receiving a TV image of a UHD resolution through an Ethernet interface; a transparency application step of capturing the OSD image so as to generate a capture screen image, and generating a color key screen image in which the transparency information has been applied to the capture screen image; a menu combining step of combining the color key screen image with the TV image; and an output step of outputting, to the UHD TV through a second HDMI interface, the combined image.

Description

METHOD AND APPARATUS FOR IMPLEMENTING THE TRANSPARENCY MENU SCREEN IN A DEVICE TO CONNECT HYDID SET-TOP BOX TO UDTV

The present invention relates to a method and apparatus for implementing a translucent menu screen in a device that allows an HD set-top box to be connected to a UHD TV. More particularly, the present invention relates to a conventional HD or full HD set-top that cannot process a UHD broadcast. The present invention relates to a method and apparatus for allowing a box to be connected to a UHD TV and displaying a translucent menu screen.

A set-top box is a device that is connected to a video reproducing apparatus such as a TV, receives signals from the outside, converts them into signals that can be reproduced by the video reproducing apparatus, and delivers them to the video reproducing apparatus. Devices that provide external signals to the set-top box include Ethernet cables, satellite receiver antennas, coaxial cables, telephone lines, and regular VHF or UHF antennas.

FIG. 23 is a conceptual diagram illustrating a conventional HD (High-Definition) or Full HD class set-top box (hereinafter, referred to as an “HD set-top box”) 10 connected to an HDTV 20. As shown in FIG. 24, the HD set-top box 10 receives and demodulates a broadcast signal including an HD video signal through a broadcast interface 12, extracts a broadcast signal of a selected channel, and the signal processor 11. Decoded in to extract the video signal, and delivers the extracted video signal to the HDTV (20) via the HDMI interface (15) for HD. The broadcast interface 12 may be a wired internet interface, a wireless internet interface, a satellite wave receiving antenna interface, a coaxial cable interface, a telephone line interface, a VHF or UHF antenna interface, or the like. The user controls the set-top box functions such as channel selection, volume control, menu display, etc. using the remote controller, and the controller 16 receives a user operation command through the remote controller receiver 17 and performs a corresponding operation. In addition, the controller 16 may download and update a new version of the set-top box software through the Ethernet interface 14, or perform various functions such as receiving a user operation command and internet shopping. On the other hand, some products may be configured to perform Internet access through the broadcast interface 12.

However, with the development of image compression technology, communication technology, and display device technology, the resolution of TV broadcasting is increasing. 4K, which is four times more clear than Full HD (1920 × 1080) due to the establishment of High Efficiency Video Coding (HEVC) standard that can compress and restore UHD (Ultra High Definition) level images and continuous price reduction of UHD class display devices. Super high definition (4K UHD) (3840 × 2160) TVs have emerged and are being spread. UHD TVs are also capable of delivering a three-dimensional picture, not just with higher resolution, but with better color reproduction.

Until now, most homes have set-top boxes that can handle HD or Full HD video. Therefore, in order to watch UHD TV, the existing HD set-top box must be replaced with a UHD set-top box capable of processing UHD images. Replacing all HD set-top boxes installed in the majority of homes with UHD set-top boxes is costly, which makes it difficult to expand the base of UHD broadcasting.

The present invention has been made in view of the above, and provides a method for displaying a translucent menu screen while allowing the use of a conventional HD or full HD set-top box, which is impossible to process UHD broadcasting, to a UHD TV. It aims to do it.

The method of the present invention comprises a first HDMI interface for connecting to an HD set-top box, a second HDMI interface for connecting to a UHD TV, and an Ethernet interface for receiving a compressed TV image of UHD resolution from the HD set-top box. The present invention relates to a method of implementing a translucent menu screen in a UHD adapter that allows an HD set-top box to be connected to a UHD TV. In addition, the method of the present invention can be applied to a UHD TV.

The method of the present invention comprises receiving an OSD image and transparency information from an HD set-top box via a first HDMI interface, receiving a UHD resolution TV image through an Ethernet interface, and capturing the OSD image to capture a screen shot. A transparency applying step of generating a color key screen to which the transparency information is applied to the captured screen, a decoding step of decoding the compressed TV image having the UHD resolution, and displaying the color key screen on the decoded TV image. And a menu synthesizing step of synthesizing and an output step of outputting the synthesized image through the second HDMI interface.

The OSD image is an image having a full-HD or HD-level resolution, the transparency applying step, the capture step of capturing the OSD image to generate a capture screen, and the upscale to upscale the capture screen to UHD-level resolution And generating a color key screen by applying the transparency information to the captured screen having the UHD resolution.

In an embodiment, the transparency information may include information about a color value to which transparency is to be applied and a transparency value to be applied. The information about the color value may include a minimum color value and a maximum color value to which transparency is applied. In this case, the UHD adapter or the UHD TV applies the transparency value as an alpha value to a pixel having a color between the lowest color value and the maximum color value.

In an exemplary embodiment, the generating of the color key screen may include generating an alpha screen by applying the transparency value as an alpha value to all pixels of the captured screen, and, for all pixels of the captured screen, the color value is the same. For pixels matching the color value information, the pixel value of the corresponding pixel of the alpha screen is obtained, the pixel value is made transparent for the pixel whose color value is a predetermined color, and the pixel of the capture screen for the remaining pixels. The method may include generating a color key screen by importing a value.

In another exemplary embodiment, the generating of the color key screen may include generating an alpha screen by applying the transparency value as an alpha value to all pixels of the captured screen, and, for all pixels of the captured screen, the color value is the same. Generating a temporary color key screen by obtaining a pixel value of a corresponding pixel of the alpha screen for a pixel corresponding to information on a color value and a pixel value of a captured screen for the remaining pixels; For all pixels of the key screen, the pixel value may be made transparent for the pixel whose color value is a predetermined color, and the pixel value of the temporary color key screen may be obtained for the remaining pixels to generate the color key screen. have.

In one embodiment, the transparency information may be menu pattern information indicating one of a plurality of predefined menu patterns. In this case, the color key screen generation step may include an alpha screen generation step of generating an alpha screen by reading information about an alpha value corresponding to the menu pattern information from a memory and applying the captured screen to the captured screen; For all pixels, the pixel value may be transparent for pixels having a predetermined color, and the pixel value of the alpha screen may be obtained for the remaining pixels to generate a color key screen.

In one embodiment, the information about the alpha value corresponding to the menu pattern information may be stored in a raster form that stores the alpha value of each pixel of the menu pattern. In this case, the UHD adapter or the UHD TV generates the alpha screen by applying the alpha value of each pixel read from the memory to the alpha value portion of the corresponding pixel of the capture screen in the alpha screen generation step.

In another embodiment, the information about the alpha value corresponding to the menu pattern information may be stored in the form of a function representing the alpha value of each pixel of the menu pattern as a function. In this case, the UHD adapter or the UHD TV generates an alpha screen by executing a function read from the memory and applying it to the alpha value portion of the captured screen in the alpha screen generation step.

In the menu synthesizing step, the UHD adapter or the UHD TV synthesizes the color value of the color key screen and the color value of the TV image according to the transparency value of each pixel of the color key screen.

The UHD adapter to which the method of the present invention is applied comprises: a first HDMI interface for connecting to an HD set-top box; A second HDMI interface for connecting to a UHD TV; An Ethernet interface for receiving a UHD resolution compressed TV image from an HD set top box; A signal processor for decoding the compressed TV image having the UHD resolution; The HD processor receives the HD resolution TV image received from the HD set-top box through the HD set-top box to the UHD image by outputting the upscaled image to the UHD TV through the HDMI interface for UHD. Receiving the OSD image and transparency information from the box through the first HDMI interface, and receiving a compressed TV image of UHD resolution through the Ethernet interface to capture the OSD image to generate a capture screen, the transparency information on the capture screen Generates the applied color key screen, decodes the compressed TV image of the UHD resolution in the signal processing unit, synthesizes the color key screen to the decoded UHD resolution TV image to the UHD TV through a second HDMI interface It is provided with the control part to output.

A UHD TV to which the method of the present invention is applied includes a UHD display device; A display driver for driving the UHD display device; An HDMI interface for connecting to an HD set-top box; An Ethernet interface for receiving a UHD resolution compressed TV image from an HD set top box; A signal processor for decoding the compressed TV image having the UHD resolution; The HD image input from the HD set-top box through the HD HDMI interface is upscaled to the UHD image by the signal processor to output the upscaled image to the UHD display device through the display driver, and from the HD set-top box to the HDMI interface. Receiving OSD image and transparency information through and receiving compressed TV image with UHD resolution through Ethernet interface, captures the OSD image to generate a captured screen, and generates a color key screen applying the transparency information to the captured screen. And decompressing the compressed TV image having the UHD resolution by the signal processor to synthesize the color key screen with the decoded TV image, and to output the synthesized image to the UHD display.

According to the present invention, the HD set-top box hardware can be used as it is by updating the software of the HD set-top box and connecting the HD set-top box to the UHD TV through the UHD adapter for the set-top box. Can be. In addition, the user can directly connect the UHD adapter for the HD set-top box between the HDMI port of the TV and the HDMI port of the set-top box, and the software applying the method of the present invention is downloaded online and installed automatically, thereby recovering the set-top box hardware. And a cumbersome procedure such as a visit to an installation technician to install a new set-top box is unnecessary. In addition, it is possible to connect a conventional HD or full HD set-top box, which is impossible to process UHD, to a UHD TV while displaying a translucent menu screen.

1 is a conceptual diagram illustrating a method of connecting a UHD adapter for an HD set-top box of the present invention.

Figure 2 is a functional block diagram showing the internal configuration of the UHD adapter for HD set-top box of the present invention.

Figure 3 is a functional block diagram showing the internal configuration of the HD set-top box used in the present invention.

4 is a flowchart illustrating operations of an HD set-top box and an UHD adapter for an HD set-top box when HD video is broadcast on a selected channel.

FIG. 5 is a flowchart illustrating operations of an HD set-top box and an UHD adapter for an HD set-top box when UHD video is broadcast on a selected channel.

FIG. 6 is a flowchart illustrating operations of an HD set-top box and an UHD adapter for an HD set-top box when processing an OSD when a UHD video is broadcast on a selected channel.

7 is a flowchart illustrating the operation of a UHD adapter for an HD set-top box for generating a temporary color key screen according to an embodiment of the present invention.

8 is a flowchart illustrating an operation of an UHD adapter for an HD set-top box generating a color key screen according to an embodiment of the present invention.

9 is a flowchart illustrating an operation of an UHD adapter for an HD set-top box generating a color key screen according to another embodiment of the present invention.

10 is an example of a TV screen on which an OSD image having a translucent menu portion is displayed.

11 is a diagram illustrating an example of a capture screen and an alpha screen.

12 is a diagram illustrating an example of a temporary color key screen.

13 is a diagram illustrating an example of a color key screen.

14 is a diagram illustrating an example of generating an OSD TV image by composing a color key screen and a TV image.

FIG. 15 is an example of an OSD TV screen on which an OSD image with a transparency gradation gradually changes and a corresponding menu pattern.

16 is an example of another OSD TV screen and a corresponding menu pattern on which an OSD image with transparency gradation gradually changes in transparency.

17 is a flowchart illustrating the operation of a UHD adapter for an HD set-top box generating a color key screen according to another embodiment of the present invention.

18 is a conceptual diagram illustrating a method of connecting an HD set-top box and the UHD TV of the present invention.

19 is a functional block diagram showing the internal configuration of the UHD TV of the present invention.

20 is a flowchart illustrating operations of an HD set-top box and a UHD TV when HD video is broadcast on a selected channel.

21 is a flowchart illustrating operations of an HD set-top box and a UHD TV when UHD video is broadcast on a selected channel.

FIG. 22 is a flowchart illustrating operations of an HD set-top box and a UHD TV when processing an OSD when a UHD video is broadcast on a selected channel.

23 is a conceptual diagram illustrating a conventional HD set-top box connected to an HDTV.

FIG. 24 is a block diagram illustrating an internal configuration of an HD set-top box that receives a broadcast signal through a broadcast interface and converts the signal into a playable signal in a video reproducing apparatus.

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

In one embodiment of the present invention by updating the software of the conventional HD set-top box to apply the method of the present invention, by connecting the UHD adapter for the HD set-top box of the present invention between the HD set-top box and a general UHD TV, It allows users to enjoy UHD video while still using the hardware of the set-top box.

In another embodiment of the present invention, by applying the present invention to a UHD TV so that the software applying the method of the present invention can use the updated HD set-top box, the hardware of the conventional HD set-top box is directly connected to the UHD TV to which the present invention is applied. To enjoy UHD video.

In the present invention, the hardware of the conventional HD set-top box is used as it is, while only partially changing the software. However, unlike conventional HD set-top boxes, UHD video can be input in addition to HD video through a broadcast interface such as a wired internet interface, a wireless internet interface, a satellite wave receiving antenna interface, a coaxial cable interface, a telephone line interface, a VHF or a UHF antenna interface. have.

One. UHD  adapter

First, an example of using a UHD adapter to connect a conventional HD set-top box to a UHD TV will be described in detail with reference to FIGS. 1 to 17.

1 is a conceptual diagram showing a method of connecting a UHD adapter between an HD set-top box and a UHD TV, Figure 2 is a functional block diagram showing the internal configuration of the UHD adapter of the present invention, Figure 3 is an HD set-top used in the present invention This is a functional block diagram showing the internal structure of the box.

The hardware of the HD set-top box 200 used in the present invention is the same as in the prior art. That is, the HD set-top box 200 receives a broadcast signal including a compressed HD image or a compressed UHD image, and a remote control receiver 217 for receiving an operation command such as channel selection and volume control from the remote controller. A broadcast interface 212 for demodulating a broadcast signal, an Ethernet interface 214 for transmitting a compressed UHD image over a wired or wireless Internet, a signal processor 211 for decoding the compressed HD image, and a TV. And an HDMI interface 215 and a controller 216 for HD for transmitting decoded video data.

The controller 216 controls the broadcast interface 212 to demodulate the broadcast signal to extract the selected broadcast channel. When the compressed HD video is received through the selected broadcast channel, the controller 216 outputs an 'upscale' command through the HDMI interface 15 for HD, and compresses the HD video, for example, by the signal processor 211. For example, it controls to decode the video compressed by the H.264 standard and output it through the HDMI interface 215 for HD. On the other hand, when a compressed UHD image (UHD resolution TV image) is received through the selected broadcast channel, the controller 216 outputs a 'UHD image display' command through the HDMI interface 215 for HD, and compresses the UHD. The image is controlled to be transmitted through a wired or wireless internet through the Ethernet interface 214.

The UHD adapter 100 of the present invention decodes an HDMI interface 120 for HD to connect the HD set-top box 200, an HDMI interface 150 for connecting to the UHD TV 300, and a compressed UHD image. The signal processor 130, an Ethernet interface 140 for receiving a compressed UHD image from the HD set-top box 200, and a controller 110. The controller 110 allows the signal processor 130 to upscale the HD image received from the HD set-top box 200 to the UHD image through the HDMI interface 120 for HD, thereby converting the upscaled image into the UHD HDMI interface ( 150 to the UHD TV (300), and through the Ethernet interface 140 to decode the compressed UHD image received from the HD set-top box 200 in the signal processing unit 130 for UHD decoded UHD image The UHD TV 300 is output through the HDMI interface 150.

The broadcast interface 212 of the HD set-top box 200 may be connected with a means for receiving broadcasts such as wired Internet, wireless Internet, satellite wave reception antenna, coaxial cable, telephone line, VHF or UHF antenna. An HDMI cable compatible with the HDMI 1.4 or lower version is connected between the HD HDMI interface 215 of the HD set-top box 200 and the HD HDMI interface 120 of the UHD adapter 100. Between the HD set-top box 200 and the UHD adapter 100, a wired or wireless Internet is also connected through Ethernet, and compressed UHD images are transmitted therethrough. The HDMI cable compatible with the HDMI 2.0 or higher version is connected between the UHD HDMI interface 150 of the UHD adapter 100 and the UHD HDMI interface 150 of the UHD TV 300.

In the present invention, the HD set-top box 200 outputs the HD video after decoding and transmits the UHD video as it is through the Ethernet without decoding.

An operation when the HD video (the HD video of the HD resolution) is received through the selected broadcast channel will be described with reference to FIG. 4. First, the HD set-top box 200 outputs an 'upscale' command through the HDMI interface 215 for HD (S40). This command is a command to upscale an HD or full-HD video (hereinafter, referred to as an "HD video") input to HDMI to a 4K resolution video (4K UHD). It is in CEC (Consumer Electronics Control) format. In addition, the HD set-top box 200 decodes the compressed HD image received through the broadcast interface 212 by the signal processor 211 and transmits it through the HDMI interface 215 for HD (S41). Data is passed to the UHD adapter 100. Then, the UHD adapter 100 subsequently scales up the HD image input to the HD HDMI interface 120 to 4K UHD resolution and outputs the HD video to the UHD TV 300 through the UHD HDMI interface 150 (S42). .

 Next, an operation when a UHD video (UHD resolution TV video) is received through the selected broadcast channel will be described with reference to FIG. 5. First, the HD set-top box 200 is a URL (uniform resource locator) address of a channel (hereinafter, referred to as a 'UHD channel') on which a UHD video currently being viewed through a content directory service (CDS) is broadcasted. To generate (S50). The HD set-top box 200 starts to operate as a digital media server (DMS) of a digital living network alliance (DLNA) (S51), and displays an HDMI- 4K-UHD image through the HDMI interface 215 for HD. The CEC command (Display 4K video) is output (S52). After receiving the command, the UHD adapter 100 starts operation as a digital media player (DMP) of the digital living network alliance (DLNA) (S53).

When the HD set-top box 200 transmits a demodulated compressed UHD video (UHD resolution compressed TV video) received through the UHD channel to the URL through the Ethernet interface 214 (S54), DMP (Digital) The UHD adapter 100 operating as a media player receives and decodes the same, and outputs the same to the UHD TV 300 through the UHD HDMI interface 150 (S55).

On the other hand, in the set top box, when the user selects a channel, the number of the corresponding channel is inserted and displayed on the currently displayed image, and when the volume is adjusted, information about the adjusted volume is inserted and displayed on the currently displayed image. This feature is called on-screen display (OSD). When the HD image is displayed, the set-top box may combine the OSD image with the HD image and output it through HDMI as in the prior art. However, since the HD set-top box 200 cannot decode or encode the UHD image, the HD set-top box 200 cannot display the OSD in this manner when the UHD image is received.

1-1. OSD function implementation first  Way

In the present invention, a first method of implementing an OSD function in a state where a UHD image is displayed will be described with reference to FIG. 6.

While receiving the compressed UHD image through the selected broadcast channel, the user should display an OSD (On Screen Display) image on the TV image when the user adjusts the volume or inquires channel information using the remote controller. An example of a TV screen on which an OSD image is displayed is shown in FIG. 10. A TV screen on which an OSD image is displayed (hereinafter, referred to as an 'OSD TV image') is a semi-transparent layer in which an opaque menu portion A in which a TV image is completely hidden and a TV image and a menu image are overlapped as shown in the example of FIG. It may have a menu portion B and a TV image portion C on which a menu is not displayed.

In this case, the control unit 216 of the HD set-top box 200 outputs an HDMI-CEC command (Display MENU) to display a menu through the HDMI interface 215 for HD (S60). In addition, the HD set-top box 200 generates an OSD image having a predetermined color except for a menu portion and outputs the OSD image through the HDMI interface 215 for HD (S61). For example, the menu portion is composed of only colors except black, and the portion of the TV image to be displayed is generated in OSD.

Meanwhile, the transparency may be expressed as an alpha part of ARGB (Alpha, Red, Green, Blue), but is transmitted from the HD set-top box 200 to the UHD adapter 100 through the HDMI interface 215 for HD. Since the data is in RGB and no alpha value is transmitted, transparency information must be transmitted separately. In the present invention, transparency information is transmitted in two ways, which will be described later.

The UHD adapter 100 that receives a menu display command from the HD set-top box 200 through the HD HDMI interface 120 while performing the operation as a DMP is connected to the HD HDMI interface 120 by the signal processor 130. Capture the input OSD (On-Screen Display) image and upscale to UHD image, and apply the transparency information received from the HD set-top box 200 to the upscaled captured image (Fig. 11 (a)) to apply color A key screen (Fig. 13) is generated (S62). The method of receiving the transparency information and generating the color key screen will be described later.

Meanwhile, the compressed UHD image received and demodulated through the UHD channel through the Ethernet interface 14 is continuously transmitted to the URL (S63). The signal processor 130 of the UHD adapter 100 decodes a compressed TV image having a UHD resolution input through the Ethernet interface 140 (S64), and a TV image having a decoded UHD resolution (FIG. 14B). The color key screen (FIG. 14 (a)) is synthesized in step S65. The synthesized OSD TV image (FIG. 14C) is output to the UHD TV 300 through the UHD HDMI interface 150 (S66).

In some embodiments, the UHD image (FIG. 14B) is stored in the video buffer, and the color key image (FIG. 14A) is stored in the frame buffer. May be synthesized to generate an OSD TV image (FIG. 14C). That is, the UHD adapter 100 inputs and decodes the UHD image (FIG. 14B) stored in the video buffer and the color key screen stored in the frame buffer (FIG. 14A). The synthesized OSD TV image (FIG. 14C) is transmitted to the UHD TV 300. When synthesizing the image stored in the video buffer and the screen stored in the frame buffer, the color value of the frame buffer and the color value of the corresponding pixel of the image stored in the video buffer are synthesized according to the transparency value of each pixel of the frame buffer. That is, when the transparency value (alpha value) is 0x00, the color value stored in the video buffer is used as it is, and for the pixel having the transparency value 0xFF, the color value stored in the frame buffer is used as it is, and the transparency value is semi-transparent. Is converted to a color value combining the color values stored in both buffers according to the transparency value.

Next, a method of transmitting transparency information and generating a color key screen will be described. In the present invention, the following two methods can be used.

<First Embodiment of Color Key Screen Generation>

In the first embodiment, the HD set-top box 200 transmits a range of colors and a transparent value of a portion to be semi-transparently displayed to the UHD adapter 100 in the HDMI-CEC command.

This will be described with reference to FIGS. 7 to 9. FIG. 11A is an example of capturing an OSD image and capturing the upscaled image, in which a black portion is a transparent portion, a blue (inner box) portion is a semi-transparent portion, and a red (star) shape. Part is the part to be opaque.

In this example, the UHD adapter 100 receives the transparency information through the HDMI-CEC command after receiving the HDMI-CEC command (Display MENU) to display the menu from the HD set-top box 200 through the HDMI interface 120 for HD. do. The transparency information includes information on color values to which transparency is to be applied and transparency values to be applied, and may be configured, for example, "transparency value = 80%, translucent color lower limit value = 0xFF000001, translucent color upper limit = 0xFF101334". Here 0xFF101334 represents dark blue. Alternatively, the transparency information may be included in the HDMI-CEC command (Display MENU) to be received.

In addition, the UHD adapter 100 receives an OSD image of HD or full-HD resolution from the HD set-top box 200 through the HDMI interface 120 for HD. Then, the UHD adapter 100 captures it and upscales it to UHD level to generate a UHD level captured screen (FIG. 11A) (step S70). The UHD adapter 100 generates an alpha screen (FIG. 11B) by applying the received transparency value (80%) as an alpha value to all pixels of the generated capture screen (step S71).

The UHD adapter 100 has a translucent color range (in this example) for the entire pixel (step S76, step S77) starting from the first pixel of the captured screen (Fig. 11 (a)) and ending with the last pixel. The pixel value of the pixel (YES in step S73) belonging to 0xFF000001 to 0xFF101334 is a pixel value (that is, a pixel value to which the alpha value is applied as the transparency value) of the alpha screen (Fig. 11 (b)). (Step S75), the pixel value of the pixel that is not in the translucent color range (No in step S73) is the pixel value of the capture screen (Fig. 11 (a)) (i.e., the pixel whose alpha value is applied as opacity (0xFF)). Value) to create a temporary color key screen (FIG. 12). Through this process, the blue portion of the temporary color key screen has an alpha value of 80%, and the remaining portion has an opacity value (0xFF).

Next, as shown in FIG. 8, the color value is generated by converting the alpha value into full transparency for the predetermined color (black in the above example) for the temporary color key screen generated as described above.

The UHD adapter 100 has a predetermined color value (black in this example) for all the pixels starting with the first pixel of the temporary color key screen (Fig. 12) (step S80) and the last pixel (step S84, step S85). ), The pixel value of the pixel (YES in step S81) is made transparent (0x00000000) (step S83), and the temporary color key screen (Fig. 12) for pixels other than the predetermined color (no in step S81). (Step S82) to generate a color key screen (Fig. 13). Through this process, the color key screen converts a pixel having 0xFF000000 (opaque black) from the temporary color key screen to 0x00000000 (transparent black). The converted screen (FIG. 13) is stored in the frame buffer. Through this process, the color key screen has a transparent portion F, an opaque portion D, and a translucent portion E having a predetermined transparency.

<Second Embodiment of Color Key Screen Generation>

Meanwhile, in the above description, a temporary color key screen is first generated by capturing an OSD image and applying transparency to an upscaled capture screen, and then 0x00 is set to an alpha value of a pixel having a color to be displayed transparently with respect to the temporary color key screen. Although a color key screen is generated by converting to a color key screen, a temporary color key screen generation process may be omitted, and a color key screen may be generated at a time by simultaneously performing a transparency application procedure and a process of converting an alpha value of a transparent color. The operation flow in this case is shown in FIG.

First, the UHD adapter 100 receives an OSD image of HD or full-HD resolution through the HDMI interface 120 for HD. It also receives information about the transparency value and the color range to which the transparency value is applied. Then, the UHD adapter 100 captures it and then upscales to UHD to generate a UHD captured screen (FIG. 11A) (step S90). The UHD adapter 100 generates an alpha screen (FIG. 11B) by applying the received transparency value (80%) to the entire captured screen (step S91).

The UHD adapter 100 has a translucent color range (in this example) for all pixels starting from the first pixel of the captured image (Fig. 11 (a)) and ending with the last pixel (step S98, step S99). The pixel value of the pixel (YES in step S93) belonging to 0xFF000001 to 0xFF101334 is the pixel value of the alpha screen (Fig. 11 (b)) (i.e., the pixel value to which the alpha value is applied as the transparency value). (Step S97), the pixel value of the pixel whose color value is a predetermined color (black in this example) (YES in step S94) is made transparent (0x00000000) (step S96), and the pixel that is not a predetermined color ( For NO in step S94, the pixel value of the capture screen (Fig. 11 (a)) is taken (step S95) to generate a color key screen (Fig. 13). Through this process, the color key screen has a transparent portion F, an opaque portion D, and a translucent portion E having a predetermined transparency.

1-2. OSD function implementation second  Way

Next, a second method of implementing the OSD function in a state where a UHD image is displayed in the present invention will be described with reference to FIGS. 15 to 17.

In the first method described above, the HDMI set-top box 200 receives the information about the color value of the menu portion to be displayed semi-transparently and the alpha value to be applied to the pixel having the color value by the HDMI-CEC command. It defines a plurality of menu patterns to be displayed in advance and uses the method of receiving information to distinguish the menu pattern by the HDMI-CEC command.

For example, as shown in the screen example of FIG. 15, an opaque portion G of the lower portion, a portion H having a transparency gradation in which the intermediate transparency is gradually changed, and a transparent portion I are formed. 1 A menu pattern, an opaque portion (J) consisting of a center and a right rectangle as shown in the screen example of FIG. 16, a semitransparent portion (K) surrounding an opaque rectangle, and a portion having a gradation on the left ( M) and a second menu pattern composed of the transparent portion L are defined in advance, and a UI number is assigned as information representing one of these menu patterns. When the display of a specific menu pattern is required, the HD set-top box 200 transmits the corresponding UI number to the UHD adapter 100 by the HDMI-CEC command. Then, the UHD adapter 100 reads the menu pattern corresponding to the received UI number from the memory and changes the alpha value of the captured screen.

In the UHD adapter 100, each menu pattern may be stored in a raster form that stores the alpha value of each pixel of the menu pattern, or stored as a function representing the alpha value of each pixel of the menu pattern as a function. May be That is, in the raster form, the alpha values of all the pixels are predefined and stored, and in the function form, the alpha values of the pixels [10, 10] to pixel [100, 100] can be stored in the form of an instruction such as 'fill alpha value 0x80'. have.

The operation of the UHD adapter 100 in the example of using the UI number as described above will be described with reference to FIG.

When the UHD adapter 100 receives an OSD image of HD or full-HD resolution through the HDMI interface 120 for HD, the UHD adapter 100 captures it and then upscales to UHD to capture UHD-class captured screen ((a of FIG. ) Is generated (step S170). In addition, the UHD adapter 100 also receives a UI number from the HD set-top box 200.

The UHD adapter 100 generates an alpha screen by reading information about an alpha value corresponding to the received UI number from a memory and applying the captured screen image to a capture screen (step S171). That is, the alpha screen is generated by applying information about the alpha value read from the memory to the alpha value portion of the capture screen. If the information about the alpha value is in the raster form, the alpha value is generated by applying the alpha value of each pixel read from memory to the alpha value part of the corresponding pixel of the capture screen, and the information about the alpha value is a function type. If is set to, the alpha screen is created by executing a function read from memory and applying it to the alpha value portion of the captured screen.

The UHD adapter 100 uses the pixel (step S173) whose color value is a predetermined color (black in this example) for all pixels starting from the first pixel of the alpha screen (step S172) and to the last pixel (step S176, step S177). The pixel value of 'Yes') is made transparent (0x00000000) (step S175), and the pixel value of the alpha screen is obtained for pixels that are not a predetermined color (No in step S173) (step S174). Create a screen. Through such a process, the color key screen has a transparent portion L, an opaque portion J, a translucent portion K, and a translucent gray portion M.

On the other hand, instead of setting the transparent portion to a predetermined color (black in the above example), the transparent portion may also be predefined according to the UI number, and the process from step S172 to step S176 may be omitted.

2. UHD  TV

When the present invention is applied to a UHD TV, an HD set-top box can be connected to a UHD TV without using a UHD adapter. An embodiment of directly connecting hardware of a conventional HD set-top box to a UHD TV to which the present invention is applied will be described in detail with reference to FIGS. 18 to 22.

18 is a conceptual diagram showing a method of connecting an HD set-top box and the UHD TV of the present invention, and FIG. 19 is a functional block diagram showing an internal configuration of the UHD TV of the present invention.

The UHD TV 400 of the present invention is similar to the configuration of a conventional UHD TV, but the HD interface 420 for connecting the HD set-top box 200 and the signal processor 430 for decoding the compressed UHD image. And a control unit configured to execute the method of the present invention. The UHD TV 400 of the present invention includes a UHD display device 460, a display driver 450 for driving the UHD display device 460, and an HDMI interface 420 for HD for connecting the HD set-top box 200. A signal processor 430 for decoding the compressed UHD image, an Ethernet interface 440 and a controller 410 for receiving the compressed UHD image from the HD set-top box 200 are provided. Although not shown, the UHD HDMI interface, a remote control receiver, and a USB interface may be provided.

The controller 410 may upscale the HD image input from the HD set-top box 200 to the UHD image by the signal processor 430 through the HDMI interface 420 for the HD and display the upscaled image in the display driver 450. The UHD display device 460 is output to the UHD display device 460, and the signal processor 430 decodes the compressed UHD image input from the HD set-top box 200 through the Ethernet interface 440. The output is performed to the UHD display apparatus 460 through 450.

The broadcast interface 12 of the HD set-top box 200 may be connected to a means for receiving broadcasts such as wired Internet, wireless Internet, satellite wave reception antenna, coaxial cable, telephone line, VHF or UHF antenna. An HDMI cable compatible with HDMI 1.4 or lower is connected between the HD HDMI interface 15 of the HD set-top box 200 and the HD HDMI interface 420 of the UHD TV 400. Between the HD set-top box 200 and the UHD TV 400, a wired or wireless Internet is also connected through Ethernet, and compressed UHD images are transmitted therethrough.

In the present invention, the HD set-top box 200 outputs the HD video after decoding and transmits the UHD video as it is through the Ethernet without decoding.

An operation in the case where an HD video (TV video with HD resolution) is received through the selected broadcast channel will be described with reference to FIG. 20. First, the HD set-top box 200 outputs an 'upscale' command through the HDMI interface 215 for HD (S200). This command is to upscale an image input through HDMI to a 4K resolution image (4K UHD), for example, in HDMI-CEC (Consumer Electronics Control) format. In addition, the HD set-top box 200 decodes the compressed HD image received through the broadcast interface 212 by the signal processor 211 and transmits the decoded HD image through the HDMI interface 215 for HD (S201). Data is delivered to the UHD TV 400. Then, the UHD TV 400 subsequently upscales the HD image input to the HD HDMI interface 420 to 4K UHD and outputs the HD image to the UHD display 460 through the display driver 450 (S202).

 Next, an operation when a UHD video (UHD resolution TV video) is received through the selected broadcast channel will be described with reference to FIG. 21. First, the HD set-top box 200 generates a uniform resource locator (URL) address of a channel (hereinafter, referred to as a 'UHD channel') on which a UHD image currently being viewed is broadcasted through a content directory service (CDS) ( S210). In addition, the HD set-top box 200 starts to operate as a digital media server (DMS) of a digital living network alliance (DLNA) (S211), and HDMI- to display 4K-UHD video through the HDMI interface 15 for HD. The CEC command (Display 4K video) is output (S212). After receiving the command, the UHD TV 400 starts operation as a digital media player (DMP) of the digital living network alliance (DLNA) (S213).

When the HD set-top box 200 transmits the demodulated compressed UHD image through the UHD channel to the URL through the Ethernet interface 214 (S214), the UHD TV 400 operating as a digital media player (DMP) is After receiving the signal, the signal processor 430 decodes the signal and outputs the UHD display 460 through the display driver 450 (S215).

A method of implementing the OSD function in a state where a UHD image is displayed in the present embodiment will be described with reference to FIG. 22.

If the user needs to display the OSD (On Screen Display) on the screen, such as adjusting the volume using the remote control or inquiring channel information while receiving the compressed UHD image through the selected broadcasting channel, the HD set-top box 200 The controller 216 outputs an HDMI-CEC command (Display MENU) for displaying a menu through the HDMI interface 215 for HD (S220). In addition, the HD set-top box 200 generates an OSD image having a predetermined color except for a menu portion and outputs the OSD image through the HDMI interface 215 for HD (S221). For example, the menu portion is composed of only colors except for black, and the portion in which the TV image except for the menu portion is to be displayed generates an OSD image composed of black. Meanwhile, the compressed UHD image received and demodulated through the UHD channel through the Ethernet interface 214 of the HD set-top box 200 is continuously transmitted to the URL (S223).

The UHD TV 400 that receives a menu display command from the HD set-top box 200 through the HD HDMI interface 420 while performing the operation as a DMP is connected to the HD HDMI interface 420 by the signal processor 430. An on-screen display (OSD) image is captured and upscaled to UHD resolution, and a color key screen reflecting an alpha value is generated on the captured screen (step S222). Since the method of generating the color key screen has been described above, a detailed description thereof will be omitted.

The UHD TV 400 decodes the UHD resolution compressed TV image input from the HD set-top box 200 through the Ethernet interface 440 (step S224), and synthesizes the decoded UHD resolution TV image and the color key screen. (S225). The synthesized OSD TV image is output to the UHD display 460 through the display driver 450 (S226).

In order to implement the OSD function in the UHD TV 400, information related to menu configuration such as alpha value or UI number is transmitted from the HD set-top box 200 to the UHD TV 400, and the information is used in the UHD TV 400. The detailed method of generating a color key screen and synthesizing with a TV image to generate an OSD TV image is similar to the OSD function implementation method in the UHD adapter 100 described with reference to FIGS. 7 to 17, and thus, a detailed description thereof is omitted. do.

As mentioned above, although the present invention has been described with some examples, the present invention is not necessarily limited to these embodiments, although all components constituting the embodiments of the present invention have been described as being combined or operating in combination. In other words, within the scope of the present invention, all of the components may be selectively operated in combination with one or more. In addition, although all of the components may be implemented in one independent hardware, each or all of the components may be selectively combined to perform some or all functions combined in one or a plurality of hardware. It may be implemented as a computer program having a. Codes and code segments constituting the computer program may be easily inferred by those skilled in the art. Such a computer program may be stored in a computer readable storage medium and read and executed by a computer, thereby implementing embodiments of the present invention. The storage medium of the computer program may include a semiconductor recording medium, a magnetic recording medium, an optical recording medium, a carrier wave medium, and the like. For example, in the above description, the case where the controller and the signal processor are configured as separate components has been described as an example. However, the controller and the signal processor may be implemented as one processor.

In addition, the terms "comprise", "comprise" or "having" described above mean that the corresponding component may be inherent unless specifically stated otherwise, and thus excludes other components. It should be construed that it may further include other components instead.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

Description

100 UHD adapter,

200 HD Set Top Box,

300 conventional UHD TVs,

400 UHD TV of the present invention.

Claims (24)

1. The HD set-top box includes a first HDMI interface for connecting to an HD set-top box, a second HDMI interface for connecting to an UHD TV, and an Ethernet interface for receiving compressed TV video of UHD resolution from the HD set-top box. As a method of implementing a translucent menu screen on a UHD adapter that allows access to a UHD TV,

   An image receiving step of receiving an OSD image and transparency information from an HD set-top box through a first HDMI interface and receiving a compressed TV image having UHD resolution through an Ethernet interface;

   A transparency application step of capturing the OSD image to generate a capture screen and generating a color key screen to which the transparency information is applied to the capture screen;

   A decoding step of decoding the compressed TV image having the UHD resolution;

   Synthesizing the color key screen with the decoded TV image;

   An output step of outputting the synthesized video to the UHD TV via the second HDMI interface

   Translucent menu screen implementation method in the UHD adapter having a.
2. The method of claim 1,

   The OSD image is a full-HD or HD resolution image,

   The transparency application step,

   A capture step of capturing the OSD image to generate a screenshot;

   An upscale step of upscaling the captured screen to a UHD level resolution;

   Color key screen generation step of generating a color key screen by applying the transparency information to the captured screen of the UHD-class resolution

   Translucent menu screen implementation method in the UHD adapter comprising a.
3. The method of claim 2,

   The transparency information is a translucent menu screen implementation method in the UHD adapter including information on the color value to apply the transparency and the transparency value to apply.
4. The method of claim 3,

   The information about the color value includes a minimum color value and a maximum color value to which transparency is applied, and the UHD adapter converts the transparency value into an alpha value for a pixel having a color between the minimum and maximum color values. How to implement semi-transparent menu screen in applied UHD adapter.
5. The method of claim 3, wherein the generating of the color key screen comprises:

   Generating an alpha screen by applying the transparency value as an alpha value to all pixels of the captured screen;

   For all pixels of the captured screen, the pixel value of the corresponding pixel of the alpha screen is obtained for the pixel whose color value matches the information about the color value, and the pixel value for the pixel whose color value is a predetermined color. To make transparent, and take the pixel value of the capture screen for the remaining pixels to create a color key screen

   Method for implementing a translucent menu screen in the UHD adapter, including.
6. The method of claim 3, wherein the generating of the color key screen comprises:

   Generating an alpha screen by applying the transparency value as an alpha value to all pixels of the captured screen;

   For all pixels of the capture screen, the pixel value of the corresponding pixel of the alpha screen is obtained for the pixel whose color value matches the information about the color value, and the pixel value of the capture screen is obtained for the remaining pixels. Creating a temporary colorkey screen,

   Generating a color key screen by bringing the pixel value of the temporary color key screen to all pixels of the temporary color key screen by making the pixel value transparent for pixels having a predetermined color and for the remaining pixels.

   Method for implementing a translucent menu screen in the UHD adapter, including.
7. The method of claim 2,

   The transparency information is a translucent menu screen implementation method of the UHD adapter, characterized in that the menu pattern information indicating one of a plurality of predefined menu patterns.
8. The method of claim 7, wherein the color key screen generating step,

   Generating an alpha screen by reading information about an alpha value corresponding to the menu pattern information from a memory and applying the same to the captured screen;

   Generating a color key screen by bringing the pixel value of the alpha screen to all pixels of the alpha screen with a pixel value of transparent color for pixels having a predetermined color and bringing the pixel value of the alpha screen to the remaining pixels.

   Method for implementing a translucent menu screen in the UHD adapter, including.
9. The method of claim 8,

   The information about the alpha value corresponding to the menu pattern information is stored in a raster form that stores the alpha value of each pixel of the menu pattern.

   The generating of the alpha screen is a method of implementing a semi-transparent menu screen in the UHD adapter, characterized in that for generating an alpha screen by applying the alpha value of each pixel read from the memory to the corresponding alpha value portion of the corresponding pixel of the capture screen.
10. The method of claim 8,

    The information about the alpha value corresponding to the menu pattern information is stored in the form of a function representing the alpha value of each pixel of the menu pattern as a function.

    The alpha screen generation step, the method to implement a translucent menu screen in the UHD adapter, characterized in that for generating an alpha screen by executing a function read from the memory to the alpha value portion of the capture screen.
11. The method according to any one of claims 1 to 10,

    The menu synthesizing step is a method of implementing a semi-transparent menu screen in the UHD adapter, characterized in that for synthesizing the color value of the color key screen and the color value of the TV image according to the transparency value of each pixel of the color key screen.
12. A method of implementing a translucent menu screen in a UHD TV that can be connected to an HD set-top box having an HDMI interface for connecting to an HD set-top box and an Ethernet interface for receiving a UHD resolution compressed TV image from the HD set-top box.

    An image receiving step of receiving an OSD image and transparency information from an HD set-top box through an HDMI interface and receiving a compressed TV image having UHD resolution through an Ethernet interface;

    A transparency application step of capturing the OSD image to generate a capture screen and generating a color key screen to which the transparency information is applied to the capture screen;

    A decoding step of decoding the compressed TV image having the UHD resolution;

    Synthesizing the color key screen with the decoded TV image;

    Output step of outputting synthesized video to UHD display

    Translucent menu screen implementation method in the UHD TV having a.
13. The method of claim 12,

    The OSD image is a full-HD or HD resolution image,

    The transparency application step,

    A capture step of capturing the OSD image to generate a screenshot;

    An upscale step of upscaling the captured screen to a UHD level resolution;

    Color key screen generation step of generating a color key screen by applying the transparency information to the captured screen of the UHD-class resolution

    Translucent menu screen implementation method in the UHD TV comprising a.
14. The method of claim 13,

    The transparency information is a translucent menu screen implementation method of the UHD TV including information on the color value to apply the transparency and the transparency value to be applied.
15. The method of claim 14,

    The information about the color value includes a minimum color value and a maximum color value to which transparency is applied, and the UHD TV sets the transparency value as an alpha value for a pixel having a color between the minimum color value and the maximum color value. How to implement semi-transparent menu screen in applied UHD TV.
16. The method of claim 14, wherein the generating of the color key screen comprises:

    Generating an alpha screen by applying the transparency value as an alpha value to all pixels of the captured screen;

    For all pixels of the captured screen, the pixel value of the corresponding pixel of the alpha screen is obtained for the pixel whose color value matches the information about the color value, and the pixel value for the pixel whose color value is a predetermined color. To make transparent, and take the pixel value of the capture screen for the remaining pixels to create a color key screen

    Method for implementing a translucent menu screen in a UHD TV, including.
17. The method of claim 14, wherein the generating of the color key screen comprises:

    Generating an alpha screen by applying the transparency value as an alpha value to all pixels of the captured screen;

    For all pixels of the capture screen, the pixel value of the corresponding pixel of the alpha screen is obtained for the pixel whose color value matches the information about the color value, and the pixel value of the capture screen is obtained for the remaining pixels. Creating a temporary colorkey screen,

    Generating a color key screen by bringing the pixel value of the temporary color key screen to all pixels of the temporary color key screen by making the pixel value transparent for pixels having a predetermined color and for the remaining pixels.

    Method for implementing a translucent menu screen in a UHD TV, including.
18. The method of claim 13,

    And the transparency information is menu pattern information representing one of a plurality of predefined menu patterns.
19. 19. The method of claim 18, wherein generating the color key screen,

    Generating an alpha screen by reading information about an alpha value corresponding to the menu pattern information from a memory and applying the same to the captured screen;

    Generating a color key screen by bringing the pixel value of the alpha screen to all pixels of the alpha screen with a pixel value of transparent color for pixels having a predetermined color and bringing the pixel value of the alpha screen to the remaining pixels.

    Method for implementing a translucent menu screen in a UHD TV, including.
20. The method of claim 19,

    The information about the alpha value corresponding to the menu pattern information is stored in a raster form that stores the alpha value of each pixel of the menu pattern.

    The alpha screen generation step is a translucent menu screen implementation method of the UHD TV, characterized in that to generate an alpha screen by applying the alpha value of each pixel read from the memory to the corresponding alpha value portion of the corresponding pixel of the capture screen.
21. The method of claim 19,

    The information about the alpha value corresponding to the menu pattern information is stored in the form of a function representing the alpha value of each pixel of the menu pattern as a function.

    The alpha screen generation step is a translucent menu screen implementation method of the UHD TV, characterized in that for generating an alpha screen by executing a function read from the memory to the alpha value portion of the capture screen.
22. The method according to any one of claims 12 to 21,

    The menu synthesizing step is a method of implementing a semi-transparent menu screen in a UHD TV, characterized in that the color value of the color key screen and the color value of the TV image is synthesized according to the transparency value of each pixel of the color key screen.
23. UHD adapter that allows you to connect your HD set-top box to a UHD TV,

    A first HDMI interface for connecting to the HD set-top box;

    A second HDMI interface for connecting to a UHD TV;

    An Ethernet interface for receiving a UHD resolution compressed TV image from an HD set top box;

    A signal processor for decoding the compressed TV image having the UHD resolution;

    The HD processor receives the HD resolution TV image received from the HD set-top box through the HD set-top box to the UHD image by outputting the upscaled image to the UHD TV through the HDMI interface for UHD. Receiving the OSD image and transparency information from the box through the first HDMI interface, and receiving a compressed TV image of UHD resolution through the Ethernet interface to capture the OSD image to generate a capture screen, the transparency information on the capture screen Generates the applied color key screen, decodes the compressed TV image of the UHD resolution in the signal processing unit, synthesizes the color key screen to the decoded UHD resolution TV image to the UHD TV through a second HDMI interface Output controller

    UHD adapter having a.
24. UHD display device;

    A display driver for driving the UHD display device;

    An HDMI interface for connecting to an HD set-top box;

    An Ethernet interface for receiving a UHD resolution compressed TV image from an HD set top box;

    A signal processor for decoding the compressed TV image having the UHD resolution;

    The HD image input from the HD set-top box through the HD HDMI interface is upscaled to the UHD image by the signal processor to output the upscaled image to the UHD display device through the display driver, and from the HD set-top box to the HDMI interface. Receiving OSD image and transparency information through and receiving compressed TV image with UHD resolution through Ethernet interface, captures the OSD image to generate a captured screen, and generates a color key screen applying the transparency information to the captured screen. And a control unit which decodes the compressed TV image having the UHD resolution by the signal processing unit, synthesizes the color key screen with the decoded TV image, and outputs the synthesized image to the UHD display.

    UHD TV equipped with.

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