JP2022155750A - Video output device - Google Patents

Abstract

To suppress a display of a black screen when switching videos to be outputted.SOLUTION: A video output device pertaining to the present invention includes a switching unit provided with a first display video input terminal to which a first video output terminal is connected, a second display video input terminal to which a second video output terminal is connected, and a display video output terminal capable of switching videos inputted to the first or the second video output terminal and displaying on a display unit, the video output device enabling execution of a first switching process of switching the switching unit so as to switch a first video outputted from the first video output terminal to a second video outputted from the second video output terminal and output the second video from the display video output terminal, and a second switching process of changing the first video outputted from the first video output terminal to the second video outputted from the first video output terminal so as to cause it to be outputted from the display video output terminal.SELECTED DRAWING: Figure 2

Description

The present invention relates to a video output device capable of outputting video to a display device or the like.

Traditionally, karaoke, in which people enjoy singing along with accompaniment, has been performed at social occasions and the like. A karaoke device used for karaoke has a basic function of outputting video and audio, like other audiovisual devices. 2. Description of the Related Art In recent years, as karaoke machines have become multi-functional, the number of images handled by karaoke machines has increased.

Patent Literature 1 discloses that in a signal receiver capable of using a plurality of images (digital signals), when one of the HDMI input terminals is switched by a switcher, a no-image (blackout) period is shortened. ing. Therefore, in this signal receiver, after authentication with the DVD recorder connected to the input terminal is completed, the switcher switches the signal receiving section.

JP 2012-19339 A

According to the signal receiver described in Patent Document 1, it is possible to shorten the no-image (blackout) period, but authentication with the connected DVD recorder is required. If a device that cannot be authenticated is connected, no image will be displayed. For example, when a customer who temporarily visits a store uses a device such as a karaoke device, a display of no image may be suspected as a malfunction of the karaoke device. Further, in the signal receiver described in Patent Document 1, a delay occurs when video is switched, so video switching cannot be performed quickly.

The present invention has been made in view of such circumstances, and aims to suppress the display of a black screen (no image, equivalent to blackout) at the time of video switching, and to quickly switch video. It is intended.

Therefore, the video output device according to the present invention employs the following configuration. A processing unit and a switching unit, the processing unit having a first video output terminal and a second video output terminal, the switching unit having a first display video input terminal to which the first video output terminal is connected, A second display video input terminal to which the second video output terminal is connected, and a display video output terminal capable of switching the video input to the first display video input terminal or the second display video input terminal and outputting it to the display unit. , when switching from the state in which the first image is output from the display image output terminal of the switching unit to the second image, the first switching process or the second switching process is executed, and the first switching process is performed by the first switching process. A process of switching the first video output from the video output terminal to the second video output from the second video output terminal by switching the switching unit, and outputting the second video from the display video output terminal, The second switching process is a process for outputting from the display video output terminal by changing the first video output from the first video output terminal to the second video output from the first video output terminal.

Furthermore, in the video output device according to the present invention, the first video output terminal and the second video output terminal of the processing unit have different resolutions of video output.

Further, in the video output device according to the present invention, the switching section includes a sub-display video output terminal capable of switching video input to the first display video input terminal or the second display video input terminal and outputting the video to the display section. .

Furthermore, the video output device according to the present invention uses either the first switching process or the second switching process according to the application program to be used.

A video output device according to the present invention includes a first processing unit, a second processing unit, and a switching unit. The first processing unit includes a first video output terminal and a video input terminal. The processing unit has a second video output terminal and a third video output terminal connected to the video input terminal, and the switching unit has a first display video input terminal connected to the first video output terminal and a second display video input terminal. a second display video input terminal to which the video output terminal is connected, and a display video output terminal capable of switching between video input to the first display video input terminal or the second display video input terminal and outputting the video to the display unit, When switching to the second video from the state in which the first video is output from the display video output terminal of the switching unit, the first switching process or the second switching process is executed, and the first switching process is the first video. The first video output from the output terminal is switched to the second video output from the second video output terminal by switching the switching unit, and the second video is output from the display video output terminal. In the second switching process, the first image output from the first image output terminal is changed to the second image output from the third image output terminal of the second processing unit and input to the image capture terminal. This is processing for outputting the second image from the display image output terminal.

A video output device according to the present invention includes a processing unit, an external video input terminal, and a switching unit. The processing unit includes a video output terminal and a video input terminal. The switching unit includes a video output terminal. The connected first display video input terminal, the second display video input terminal to which the external video input terminal is connected, and the video input to the first display video input terminal or the second display video input terminal are switched and displayed. When switching to the second image from the state in which the first image is output from the display image output terminal of the switching unit, the first switching process or the second switching process is performed. The first switching process switches the first video output from the video output terminal to the second video input to the external video input terminal by switching the switching unit, and outputs the second video from the display video output terminal. In the second switching process, the first video output from the video output terminal is changed to the second video input from the external video input terminal to the video capture terminal, thereby outputting the display video. This is processing for outputting the second image from the output terminal.

According to the video output device of the present invention, it is possible to suppress the display of a black screen when switching the video to be output.

The figure which shows the structure of the karaoke system of this embodiment. FIG. 4 is a diagram showing the configuration of the control unit of this embodiment; FIG. 4 is a diagram for explaining the operation of the control unit during the first switching process of the embodiment; A flow chart showing the first switching process of the present embodiment. FIG. 4 is a diagram for explaining the operation of the control unit during the second switching process of the present embodiment; FIG. 4 is a diagram for explaining the operation of the control unit during the second switching process of the present embodiment; A flow chart showing the second switching process of the present embodiment. FIG. 4 is a diagram for explaining the operation of the control unit during the third switching process of the embodiment; FIG. 4 is a diagram for explaining the operation of the control unit during the third switching process of the embodiment; FIG. 4 is a diagram for explaining the operation of the control unit during the third switching process of the embodiment; Flow diagram showing the third switching process of the present embodiment

FIG. 1 is a diagram showing the configuration of a karaoke system according to this embodiment. The karaoke system in this embodiment includes a karaoke device 2 (also called a commander) and a remote control device 1 . The karaoke machine 2 and the remote control device 1 are connected for communication so as to form a network using the LAN 100 and the access point 130 . The karaoke machine 2 of this embodiment corresponds to a video output device according to the present invention.

The karaoke device 2 includes a control section 20 that performs various processes such as playing music and displaying a background image. The control unit 20 can perform various types of processing such as reproduction of music information and reproduction of background images. A display image output terminal 21a and a sub-display image output terminal 21b for outputting images are connected to the control section 20 . A first monitor 41a is connected to the display image output terminal 21a, and a second monitor 41b is connected to the sub-display image output terminal 21b. An external video input terminal 22 is also connected for connecting an external device and capturing video. In this embodiment, terminals using the HDMI (registered trademark) standard are adopted as these terminals.

Various components are connected to the control unit 20 via an interface 33 . In this embodiment, the mixing amplifier 34, the hard disk 35 as a storage unit for storing various information, various communication means (infrared communication unit 36, wireless LAN communication unit 37, LAN communication unit 38), operation for receiving various inputs from the user. It has a portion 39 .

The mixing amplifier 34 mixes the music sound played by the control unit 20 and the singing voice input from the microphones 43 a and 43 b and outputs the mixed sound to the speaker 42 . In this embodiment, the infrared communication unit 36 is used to communicate with the remote control device 1 and to receive music designation and the like from the remote control device 1 . The LAN communication unit 38 functions as communication means for connecting to the LAN 100 and joining the network. The karaoke machine 2 of the present embodiment also includes a wireless LAN communication unit 37, and instead of a wired network connection using the LAN communication unit 38, a wireless network connection using the wireless LAN communication unit 37b can be performed. is also possible.

With such a configuration, the karaoke device 2 executes various types of processing, and the main functions of the karaoke device 2 are music reservation processing, music reproduction processing, and the like. The music reservation processing is processing for designating and reserving music based on designation from the user, and is executed in cooperation with the remote control device 1 . The reservation information formed by the music selection process of the remote control device 1 is transmitted to the karaoke device 2 . The karaoke machine 2 registers the received reservation information in the reservation table in the memory. The music reproduction process is a process of reproducing the reserved music, and is a process in which the music performance process and the lyric display process are executed in synchronization.

On the other hand, the remote control device 1 can execute music selection processing of searching for music based on an instruction from the user and transmitting reservation information to the karaoke device 2 for the music for which a reproduction instruction has been given. Further, the remote control device 1 can receive various information from the karaoke device 2 or the server device 5 connected to the Internet and execute various processes. In this embodiment, an operation unit 17 and a touch panel monitor 11 are provided as user interfaces for receiving various instructions from the user. The touch panel monitor 11 includes a display section 11a and a touch panel 11b, and displays various interfaces on the display section 11a and can receive touch input from the user.

Furthermore, the remote control device 1 has a memory 14 as a storage unit for storing a database required for music selection processing, various programs, and various information generated along with the execution of the programs, and a memory 14 for collectively controlling these components. and a remote controller side control unit. The controller on the remote control side includes a CPU 15, an image control unit 13 for forming an image to be displayed on the touch panel monitor 11, a video RAM 12 for temporarily storing image information to be displayed, and an input from the touch panel monitor 11 or the operation unit 17. and an operation processing unit 18 for transmitting to the CPU 15.

The remote control device 1 is wirelessly connected to the access point 130 by the wireless LAN communication unit 16 , thereby being connected to the network formed by the LAN 100 . Each remote control device 1 is associated with a specific karaoke device 2 in advance. Various commands output from the remote control device 1 are received by the associated karaoke device 2 . In addition, the remote control device 1 is provided with an infrared communication section 19, and is capable of transmitting reservation information and the like when music is reserved to the infrared communication section 36 on the karaoke device 2 side.

With such a configuration of the remote control device 1, various inputs from the user are received from the touch panel monitor 11 or the operation unit 17, and video information is displayed on the touch panel monitor 11 to provide various information to the karaoke device 2. It is possible to perform various processes such as music selection processing for transmitting reservation information to be output.

FIG. 2 is a diagram showing the configuration of the control unit 20 of this embodiment. The control unit 20 of the present embodiment includes a switching unit 23, a first SoC 24a (corresponding to a "processing unit" or a "first processing unit" according to the present invention), a second SoC 24b (corresponding to a "second processing unit" according to the present invention, ), a first converter 25 , a second converter 26 , a sub-switcher 27 and a third converter 28 . The switching unit 23 can switch the video output from the first SoC 24a, the second SoC 24b, and the sub-switching unit 27 to output to the display video output terminal 21a or the sub-display video output terminal 21b. Here, SoC (System on a Chip) is a chip that integrates functions necessary for controlling the karaoke apparatus 2, such as a CPU and memory.

The first SoC 24a corresponds to the "processing unit" or "first processing unit" in the present invention. Also, the second SoC 24b corresponds to the "second processing unit" in the present invention. Note that the (first) processing unit and the second processing unit may be realized by a plurality of parts such as a CPU and a memory instead of the SoC form.

The first SoC 24a is provided with a 1-1 video output terminal 241a and a 1-2 video output terminal 241b as terminals for outputting video. The 1-1 video output terminal 241a outputs a video signal having HDMI (registered trademark) and 4K resolution. The video signal output from the 1-1 video output terminal 241 a is input to the first display video input terminal 23 a of the switching section 23 .

Also, the 1-2 video output terminal 241b outputs a video signal which is LVDS (Low Voltage Differential Signaling) and has a resolution of 1080p. In this embodiment, the first conversion unit 25 converts the video signal into an HDMI standard video signal. The video signal converted by the first conversion section 25 is input to the second display video input terminal 23b of the switching section 23 .

In the first SoC 24a, the video signal output from the 1-1 video output terminal 241a and the video signal output from the 1-2 video output terminal 241b are formed independently, that is, different video signals are formed and output. is possible.

Also, the first SoC 24a is provided with a 1-1 image acquisition terminal 242a and a 1-2 image acquisition terminal 242b. The 1-1 video take-in terminal 242a can take in (capture) the video signal output from the second SoC 24b. On the other hand, the 1-2 video input terminal 242b is capable of capturing (capturing) an external video signal output from the sub-switching section 27. FIG. In the present embodiment, a CSI video signal having a resolution of 1080p is captured from the 1-1 video capturing terminal 242a, and a CSI video signal having a resolution of 720p is captured from the 1-2 video capturing terminal 242b. and

The second SoC 24b is provided with a 2-1 video output terminal 243a and a 2-2 video output terminal 243b as terminals for outputting video. The 2-1 video output terminal 243a outputs a video signal with HDMI and 4K resolution. The video signal output from the 2-1 video output terminal 243 a is input to the third display video input terminal 23 c of the switching section 23 .

A LVDS video signal having a resolution of 1080p is output from the 2-2 video output terminal 243b. In this embodiment, it is converted into a CSI video signal by the second converter 26 . The video signal converted by the second converter 26 is input to the 1-1 video input terminal 242a of the first SoC 24a.

The sub-switching unit 27 has a function of switching and outputting an HDMI standard video signal. The sub-switching unit 27 switches the HDMI standard video signal input from the external video input terminal 22 to the 3-1 video output terminal 271a or the 3-2 video output terminal 271b and outputs it. The video signal output from the 3-1 video output terminal is input to the fourth display video input terminal 23 d of the switching section 23 . The video signal output from the 3-2 video output terminal is converted into a CSI video signal with a resolution of 720p in the third converter 28, and is input to the 1-2 video input terminal 242b of the first SoC 24a.

In the present embodiment, by using such a configuration of the control section 20, it is possible to output the image to be displayed from the display image output terminal 21a and the sub-display image output terminal 21b. By the way, in the switching unit 23 that switches and outputs the video signal of the HDMI standard, a black screen (also referred to as a non-display period, blackout) occurs at the time of switching. Therefore, when a black screen appears on the first monitor 41a and the second monitor 41b, the user may misunderstand that the karaoke machine 2 or the first monitor 41a and the second monitor 41b are out of order. be.

One object of the present embodiment is to switch the video so that the black screen that occurs in the switching unit 23 does not occur. In addition, in this embodiment, it is also possible to switch images using the switching unit 23, and it is also possible to switch images using the switching unit 23 depending on circumstances such as the resolution of the image to be displayed. It has become.

In this embodiment, video can be switched in three embodiments. Three embodiments are described below.

(First embodiment)
FIG. 3 is a diagram for explaining the operation of the control unit 20 during the first switching process in the first embodiment. In the first embodiment, only the first SoC 24a having two video output systems is used. FIGS. 3A to 3B2 extract only the configuration used in the first embodiment in the control section 20. FIG. In the first embodiment, the switching unit 23, the first SoC 24a, the first conversion unit 25, the display video output terminal 21a, and the sub-display video output terminal 21b are used. Note that the first conversion unit 25 may not necessarily be provided depending on the format of the video signal used.

FIG. 3A is a diagram showing an example before switching the video signal. In this example, the image L1 is output from the 1-1 image output terminal 241a, and the image L2 is output from the 1-2 image output terminal 241b. In the switching unit 23, the first display video input terminal 23a is connected to the display video output terminal 21a, and the second display video input terminal 23b is connected to the sub-display video output terminal 21b.

In the state of FIG. 3A, the image L1 is output from the display image output terminal 21a, and the image L2 is output from the sub-display image output terminal 21b. Here, in the state of FIG. 3A, switching is performed to replace the image L1 output from the display image output terminal 21a and the image L2 output from the sub-display image output terminal 21b. This corresponds to the image output state of FIG. 3 (B1) and FIG. 3 (B2).

FIG. 3B1 shows a case in which images are switched by switching the switching unit 23. FIG. In this case, the switching unit 23 switches the first display video input terminal 23a to the sub-display video output terminal 21b and switches the second display video input terminal 23b to the display video output terminal 21a, thereby switching the video. However, in this case, since switching is performed by the switching unit 23, a black screen is generated on the first monitor 41a and the second monitor 41b.

On the other hand, in FIG. 3B2, the switching unit 23 is not switched, and in the first SoC 24a, the video output from the 1-1 video output terminal 241a and the video output from the 1-2 video output terminal 241b is being replaced. In this case, the image L2 can be output from the display image output terminal 21a and the image L2 can be output from the sub-display image output terminal 21b without switching the switching unit 23. FIG.

Whether to switch to FIG. 3 (B1) or to FIG. 3 (B2) can be selectively performed depending on circumstances such as the presence or absence of a black screen and the resolution required for the images L1 and L2. is. FIG. 4 shows a flow diagram of the first switching process for selectively switching the video by the switching unit 23 and switching the video by the first SoC 24a.

The first switching process is performed by the first SoC 24a, the second SoC 24b, or another processing unit provided. When the first switching process is started, input of a switching instruction is waited (S101). The switching instruction corresponds to an input by a user or a command generated on an application program such as the progress of processing. The switching instruction includes an instruction to determine whether or not to switch using the switching unit 23 .

If switching is performed by the switching unit 23 (S102: Yes), the video is switched using the switching unit 23 (S103). In the example of FIG. 3, this corresponds to switching from the state of FIG. 3A to the state of FIG. 3B1. In this case, since the TMDS (Transition Minimized Differential Signaling) signal is cut off in the HDMI standard video signal, a black screen occurs on the first monitor 41a and the second monitor 41b (S104). When the TMDS signal is reconnected, the first monitor 41a and the second monitor 41b detect the input signal and start displaying images (S105).

On the other hand, when switching by the switching unit 23 is not used (S103: No), switching is performed inside the first SoC 24a. In the example of FIG. 3, this corresponds to switching from the state of FIG. 3A to the state of FIG. 3B2. In this case, video output starts from the next frame after switching in the first SoC 24a (S107).

As described above, in the first embodiment, by switching the video inside the first SoC 24a having a plurality of video output systems, it is possible to perform video switching without a black screen. In addition, it is also possible to switch images by the switching unit 23, and it is possible to selectively use both according to various circumstances such as the resolution of images to be displayed and output.

(Second embodiment)
5 and 6 are diagrams for explaining the operation of the control unit 20 during the second switching process in the second embodiment. In the second embodiment, the video output from the first SoC 24a and the second SoC 24b is used. FIGS. 5A to 6B2 extract only the configuration used in the second embodiment in the control section 20. FIG. In the second embodiment, the switching unit 23, the first SoC 24a, the second SoC 24b, the second conversion unit 26, the display video output terminal 21a, and the sub-display video output terminal 21b are used. Note that the second conversion unit 26 may not necessarily be provided depending on the format of the video signal used.

FIG. 5A is a diagram showing an example before switching the video signal. In this example, the first SoC 24a outputs the video L from the 1-1 video output terminal 241a to the first display video input terminal 23a of the switching section 23. FIG. In the switching unit 23, the first display video input terminal 23a is connected to the display video output terminal 21a and the sub-display video output terminal 21b.

Therefore, in the state of FIG. 5A, the image L1 formed by the first SoC 24a is output from the display image output terminal 21a and the sub-display image output terminal 21b. Here, in the state of FIG. 5A, a process of switching the image L output from the display image output terminal 21a and the sub-display image output terminal 21b to the image A formed by the second SoC 24b is executed. This corresponds to the image output state of FIG. 6 (B1) and FIG. 6 (B2).

FIG. 6B1 shows a case where the video is switched by switching the switching unit 23. FIG. In this case, the switching unit 23 switches the path from the third display video input terminal 23c to the display video output terminal 21a and the sub-display video output terminal 21b, thereby switching to the video A output from the second SoC 24b. However, in this case, since switching is performed by the switching unit 23, a black screen is generated on the first monitor 41a and the second monitor 41b.

On the other hand, in FIG. 6B2, the display video output terminal 21a and the sub-display video output are output by outputting the video A captured by the first SoC 24a from the 1-1 video output terminal 241a without switching the switching unit 23. The image output from the terminal 21b is switched. In this case, the image A can be output from the display image output terminal 21a and the sub-display image output terminal 21b without switching the switching unit 23. FIG. Although the video output from the 1-1 video output terminal 241a of the first SoC 24a has a resolution of 4K, the resolution is restricted to 1080p by passing through the second conversion unit .

Whether to switch to FIG. 6 (B1) or to switch to FIG. 6 (B2) can be selectively performed depending on circumstances such as the presence or absence of a black screen and the resolution required for video L and video A. be. FIG. 7 shows a flow diagram of a second switching process for selectively switching the video by the switching unit 23 and switching the video of the second SoC 24b captured by the first SoC 24a.

The second switching process is performed by the first SoC 24a, the second SoC 24b, or another processing unit provided. When the second switching process is started, it waits for an input of a switching instruction (S201). As in the first switching process, the switching instruction corresponds to an input by the user or a command generated on the application program such as the progress of the process. The switching instruction includes an instruction to determine whether or not to switch using the switching unit 23 .

When switching is performed by the switching unit 23 (S202: Yes), the video is switched using the switching unit 23 (S203). In the examples of FIGS. 5 and 6, this corresponds to switching from the state of FIG. 5A to the state of FIG. 6B1. In this case, since the TMDS signal is cut off in the HDMI standard video signal, a black screen occurs on the first monitor 41a and the second monitor 41b (S204). When the TMDS signal is reconnected, the first monitor 41a and the second monitor 41b detect the input signal and start displaying images (S205).

On the other hand, if the switching of the switching unit 23 is not used (S203: No), the first SoC 24a converts the video output from the 1-1 video output terminal 241a to the captured video acquired from the 1-1 video capture terminal 242a. (S206). In the examples of FIGS. 5 and 6, this corresponds to switching from the state of FIG. 5A to the state of FIG. 6B2. In this case, video output starts from the next frame after switching in the first SoC 24a (S207).

As described above, in the second embodiment, when switching between images formed by the first SoC 24a and the second SoC 24b, switching to the captured image captured by the first SoC 24a enables image switching without a black screen. Moreover, it is also possible to switch images using the switching unit 23, and it is possible to selectively use both according to various circumstances such as the resolution of the image to be displayed and output.

(Third Embodiment)
8 to 10 are diagrams for explaining the operation of the control unit 20 during the third switching process in the third embodiment. In the third embodiment, the video output from the first SoC 24 a is switched to the video captured from the external video input terminal 22 . 8 to 10 extract only the configuration used in the third embodiment in the control unit 20. FIG. In the third embodiment, the switching unit 23, the first SoC 24a, the sub-switching unit 27, the third conversion unit 28, the display video output terminal 21a, the sub-display video output terminal 21b, and the external video input terminal 22 are used. . Note that the third conversion unit 28 may not necessarily be provided depending on the format of the video signal used.

FIG. 8A is a diagram showing an example before switching the video signal. In this example, the first SoC 24a outputs the video L from the 1-1 video output terminal 241a to the first display video input terminal 23a of the switching section 23. FIG. In the switching unit 23, the first display video input terminal 23a is connected to the display video output terminal 21a and the sub-display video output terminal 21b.

Therefore, in the state of FIG. 8A, the image L1 formed by the first SoC 24a is output from the display image output terminal 21a and the sub-display image output terminal 21b. Here, in the state of FIG. 8A, a process of switching the image L output from the display image output terminal 21a and the sub-display image output terminal 21b to the image Aux input from the external image input terminal 22 is executed. This corresponds to the image output state of FIG. 9 (B1) and FIG. 10 (B2).

FIG. 9B1 shows a case where the video is switched by switching the switching unit 23. FIG. In this case, the switching unit 23 switches the path from the fourth display video input terminal 23d to the display video output terminal 21a and the sub-display video output terminal 21b, thereby switching to the video Aux input from the external video input terminal 22. At that time, the sub-switching unit 27 is previously switched to the path from the video input terminal 272 to the 3-1 video output terminal 271a. In this case, a black screen is generated on the first monitor 41a and the second monitor 41b because switching by the switching unit 23 is required.

On the other hand, in FIG. 10B2, the display video output terminal 21a and the sub-display video output are output by outputting the video Aux captured by the first SoC 24a from the 1-1 video output terminal 241a without switching the switching unit 23. The image output from the terminal 21b is switched to the image Aux. In this case, the video Aux can be output from the display video output terminal 21a and the sub-display video output terminal 21b without switching the switching unit 23. FIG. Although the video output from the 1-1 video output terminal 241a of the first SoC 24a has a resolution of 4K, its resolution is limited to 720p by passing through the third converter .

Whether switching to FIG. 9B1 or switching to FIG. be. FIG. 11 shows a flow diagram of third switching processing for selectively switching video by the switching unit 23 and switching video from the external video input terminal 22 captured by the first SoC 24a.

The third switching process is performed by the first SoC 24a, the second SoC 24b, or another processing unit provided. When the third switching process is started, input of a switching instruction is waited (S301). As in the first switching process, the switching instruction corresponds to an input by the user or a command generated on the application program such as the progress of the process. The switching instruction includes an instruction to determine whether or not to switch using the switching unit 23 .

If switching is to be performed by the switching unit 23 (S302: Yes), first, as shown in FIG. 271a (S303). It should be noted that this switching process is omitted when this route has already been taken.

After that, the video is switched using the switching unit 23 (S304). 8 to 10 correspond to switching from the state of FIG. 8A to the state of FIG. 9B1. In this case, since the TMDS signal is cut off in the HDMI standard video signal, a black screen occurs on the first monitor 41a and the second monitor 41b (S305). When the TMDS signal is reconnected, the input signal is detected on the first monitor 41a and the second monitor 41b, and the image starts to be displayed (S306).

On the other hand, if the switching of the switching unit 23 is not used (S303: No), first, the sub-switching unit 27 is switched from the third conversion unit 28 side, that is, from the video input terminal 272 as shown in FIG. 9B2. The path is switched to the 3-2 video output terminal 271b (S307). It should be noted that this switching process is omitted when this route has already been taken. As with the switching unit 23, the secondary switching unit 27 causes a black screen when switching. A black screen does not appear in the video output from the display video output terminal 21b.

The first SoC 24a switches the video output from the 1-1 video output terminal 241a to the captured video acquired from the 1-2 video capture terminal 242b (S308). In the examples of FIGS. 8 to 10, this corresponds to switching from the state of FIG. 8A to the state of FIG. 10B2. In this case, video output starts from the next frame after switching in the first SoC 24a (S309).

Thus, in the third embodiment, when switching between the video formed by the first SoC 24a and the video input from the external video input terminal 22, switching to the captured video captured by the first SoC 24a enables video switching without a black screen. It is possible to do Moreover, it is also possible to switch images using the switching unit 23, and it is possible to selectively use both according to various circumstances such as the resolution of the image to be displayed and output.

(Modification)
In the first to third embodiments described above, the display video output terminal 21a and the sub-display video output terminal 21b are used to display and output to two monitors 41a and 41b. Here, the output of the switching unit 23 is not limited to two systems as described above, and may be one system output. Alternatively, it may have three or more outputs.

As described above, the video output device of the present embodiment has been described by taking video switching in the karaoke device 2 as an example, but the video output device is not limited to the karaoke device, and can be a remote control device 1, a personal computer, or a game. It may be various information processing devices such as machines. Further, a video output program that is executed by such various information processing devices and realizes video switching similar to that of the karaoke device 2 of the present embodiment also belongs to the scope of the present invention.

1: remote control device 26: second conversion unit 2: karaoke device 27: sub-switching unit 5: server device 28: third conversion unit 11: touch panel monitor 33: interface 11a: display unit 34: mixing amplifier 11b: touch panel 35: hard disk 12: Video RAM 36: Infrared communication unit 13: Video control unit 37: Wireless LAN communication unit 14: Memory 37b: Wireless LAN communication unit 15: CPU 38: LAN communication unit 16: Wireless LAN communication unit 39: Operation unit 17: Operation Unit 41a: First monitor 18: Operation processing unit 41b: Second monitor 19: Infrared communication unit 42: Speaker 20: Control unit 43a: Microphone 21a: Display image output terminal 43b: Microphone 21b: Sub-display image output terminal 130: Access Point 22: External video input terminal 241a: 1 video output terminal 23: Switching section 241b: 2 video output terminal 23a: 1st display video input terminal 242a: 1 video capture terminal 23b: 2nd display video input terminal 242b: 2 video Input terminal 23c: 3rd display image input terminal 243a: 1st image output terminal 23d: 4th display image input terminal 243b: 2nd image output terminal 24a: 1st SoC 271a: 1st image output terminal 24b: 2nd SoC 271b: 2nd image output Terminal 25: First converter 272: Video input terminal

Claims (6)

A processing unit and a switching unit,
The processing unit has a first video output terminal and a second video output terminal,
The switching unit includes a first display video input terminal to which the first video output terminal is connected, a second display video input terminal to which the second video output terminal is connected, and a first display video input terminal or a second display video input. Equipped with a display video output terminal that can switch the video input to the terminal and output it to the display,
When switching to the second image from the state in which the first image is output from the display image output terminal of the switching unit, executing the first switching process or the second switching process,
In the first switching process, the first image output from the first image output terminal is switched to the second image output from the second image output terminal by switching the switching unit, and the second image is output from the display image output terminal. It is a process to output video,
The second switching process is a process for outputting from the display video output terminal by changing the first video output from the first video output terminal to the second video output from the first video output terminal. Device. 2. The video output device according to claim 1, wherein the first video output terminal and the second video output terminal of the processing unit have different resolutions of video output. 3. The image according to claim 1, wherein the switching unit includes a sub-display image output terminal capable of switching the image input to the first display image input terminal or the second display image input terminal and outputting it to the display unit. output device. 4. The video output device according to any one of claims 1 to 3, wherein either the first switching process or the second switching process is used according to the application program to be used. A first processing unit, a second processing unit, and a switching unit,
The first processing unit has a first video output terminal and a video capture terminal,
The second processing unit has a second video output terminal and a third video output terminal connected to the video input terminal,
The switching unit includes a first display video input terminal to which the first video output terminal is connected, a second display video input terminal to which the second video output terminal is connected, and a first display video input terminal or a second display video input. Equipped with a display video output terminal that can switch the video input to the terminal and output it to the display,
When switching to the second image from the state in which the first image is output from the display image output terminal of the switching unit, executing the first switching process or the second switching process,
In the first switching process, the first image output from the first image output terminal is switched to the second image output from the second image output terminal by switching the switching unit, and the second image is output from the display image output terminal. It is a process to output video,
The second switching process changes the first image output from the first image output terminal to the second image output from the third image output terminal of the second processing unit and input to the image capture terminal. , a process for outputting the second video from the display video output terminal. Equipped with a processing unit, an external video input terminal, and a switching unit,
The processing unit has a video output terminal and a video capture terminal,
The switching unit has a first display video input terminal to which the video output terminal is connected, a second display video input terminal to which the external video input terminal is connected, and inputs to the first display video input terminal or the second display video input terminal. Equipped with a display video output terminal that can switch the video to be displayed and output to the display unit,
When switching to the second image from the state in which the first image is output from the display image output terminal of the switching unit, executing the first switching process or the second switching process,
The first switching process switches the first video output from the video output terminal to the second video input to the external video input terminal by switching the switching unit, and outputs the second video from the display video output terminal. is a process that causes
The second switching process changes the first video output from the video output terminal to the second video input from the external video input terminal to the video capture terminal, thereby outputting the second video from the display video output terminal. video output device

Images