JP5010671B2 - VIDEO DISPLAY DEVICE, VIDEO REPRODUCTION DEVICE, VIDEO DISPLAY METHOD, AND VIDEO REPRODUCTION METHOD - Google Patents

Description

  The present invention relates to a video display device having a super-resolution function, a video playback device, a video display method, and a video playback method.

  In recent years, opportunities to view video content on a display for a personal computer having a resolution exceeding the SD (Standard Definition) standard are increasing. Also, with the full-fledged high-definition broadcasting, television receivers compliant with HD (High Definition) standards have become widespread in ordinary households.

  Compared with a video display device having such a high resolution, video data acquired by a photographing device such as a video camera, a television broadcast conforming to the SD standard, a DVD, or the like has a low resolution. For this reason, it is necessary to increase the resolution of the video data by some means. Also, when a part of the video is enlarged and displayed, or when shooting with the digital zoom beyond the optical zoom when using the video camera, it is necessary to increase the resolution.

  Conventionally, linear interpolation and interpolation by three-dimensional convolution (Cubic Convolution) have been used for high resolution, but there is a problem that sufficient sharpness cannot be obtained. Therefore, research on super-resolution technology that generates images that exceed the original resolution of images by creating new pixel value data between pixels, creating high frequency components, and sharpening them is proceeding. It has been. In addition, development for incorporating a super-resolution function into the video input / output device as described above is also in progress. Therefore, in the future, video display devices and video playback devices having a super-resolution function are expected to become popular.

  In Patent Document 1, in a video / audio reproduction system in which a TV, an AV amplifier, a DVD player, and the like are combined, the system is configured according to the presence / absence and format of the video and audio signals of the content recorded on the optical disk to be reproduced. A video / audio reproduction system for automatically setting a device to an optimum operating state is disclosed. The user can view the content in an optimal state without any specific instruction only by playing the optical disc.

JP 2007-179707 A

  However, the video / audio reproduction system of Patent Document 1 controls devices constituting the system based on a content format, and is not based on a function of each device. For this reason, when both the video display device and the video playback device have the above-described super-resolution function, the super-resolution conversion processing having a sharpening effect is performed twice on the video to be played back. It will be. In this case, there is a possibility that the image quality is deteriorated due to excessive emphasis of noise and outline.

  In order to prevent such deterioration, it is necessary to perform control for executing the super-resolution conversion process only in either the video display device or the video playback device.

  The present invention has been made in consideration of the above-described circumstances, and a video display device, a video playback device that performs control for executing super-resolution conversion processing only in either the video display device or the video playback device, It is an object to provide a video display method and a video playback method.

  In order to solve the above-described problem, a video display device according to one aspect of the present invention includes a video receiving unit that receives a video signal subjected to sharpening processing from an external video reproduction device, and the video signal, Image quality processing means for performing image quality processing including sharpening processing; and a signal for weakening the effect of the sharpening processing of the external video reproduction device as compared to when the image quality processing does not include the sharpening processing, Signal transmitting means for transmitting to an external video reproduction apparatus.

  A video display method according to another aspect of the present invention receives a video signal subjected to sharpening processing from an external video playback device, and performs image quality processing including sharpening processing on the video signal. And transmitting a signal for weakening the effect of the sharpening process of the external video reproduction device to the external video reproduction device as compared with the case where the sharpening process is not included in the image quality processing. It is characterized by that.

  According to the present invention, control for executing the super-resolution conversion process can be performed only in either the video display device or the video playback device.

1 is a block diagram showing a configuration of a digital television receiver as an example of a video display device according to an embodiment of the present invention. The block diagram which shows the structure of the video process part in the video display apparatus of the embodiment. The block diagram which shows control of super-resolution conversion process execution at the time of connecting a video reproduction apparatus to the video display apparatus of the embodiment. 6 is a flowchart showing an operation in the case of notifying the video playback device that the video display device has a super-resolution function in the video display device of the embodiment. 6 is a flowchart showing an operation when receiving a notification from the video playback device that it has a super-resolution function in the video display device of the embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  First, a digital television receiver as an example of a video display apparatus according to an embodiment of the present invention will be described with reference to FIG.

  The digital television receiver 11 includes a video display 14, a speaker 15, an operation unit 16, a light receiving unit 18, a card holder 70, 72, a LAN terminal 21, an HDMI terminal 22, 23, a USB terminal 24, i. Link terminal 25, broadcast signal input terminals 48 and 53, analog signal input terminals 60a to 60d, output terminals 63 and 64, tuners 49, 54 and 56, card I / F (interface) 69 and 71, communication I / F 73, first 1 HDMI I / F74, 2nd HDMI I / F75, USB I / F76, i. Link I / F77, PSK demodulator 50, OFDM demodulator 55, analog demodulator 57, signal processing unit 51, audio processing unit 59, graphic processing unit 58, OSD signal generation unit 61, video processing unit 62, control unit 65, etc. It has.

  Also, a BS / CS digital broadcast receiving antenna 47 and a terrestrial broadcast receiving antenna 52 are connected to the broadcast signal input terminal 48 and the broadcast signal input terminal 53, respectively. The light receiving unit 18 receives a signal output from the remote controller 17. The card holder 70 and the card holder 72 are loaded with the first memory card 19 and the second memory card 20, respectively.

  The control unit 65 controls the operation of each unit in the digital television receiver 11. The control unit 65 includes a CPU and the like, and includes a ROM 66, a RAM 67, and a nonvolatile memory 68. The ROM 66 stores a control program executed by the CPU built in the control unit 65. Various setting information and control information are stored in the nonvolatile memory 68. The CPU loads the instruction group and data necessary for the processing into the RAM 67 and executes the processing.

  Operation information by the operation unit 16 or operation information by the remote controller 17 received by the light receiving unit 18 is input to the control unit 65. The control unit 65 reflects each operation and controls each unit in the digital television receiver 11.

  The control unit 65 can perform information transmission with the first memory card 19 attached to the card holder 70 via the card I / F 69. Similarly, the control unit 65 can perform information transmission with the second memory card 20 attached to the card holder 72 via the card I / F 71.

  The control unit 65 is connected to the LAN terminal 21 via the communication I / F 73. Accordingly, the control unit 65 can perform information transmission with the LAN-compatible HDD connected to the LAN terminal 21 via the communication I / F 73, for example. In this case, the control unit 65 has a DHCP (Dynamic Host Configuration Protocol) server function, and assigns and controls an IP (Internet Protocol) address to a LAN-compatible HDD connected to the LAN terminal 21.

  The control unit 65 is connected to the first HDMI terminal 22 via the first HDMI I / F 74. Accordingly, the control unit 65 can perform information transmission with each device connected to the first HDMI terminal 22 via the first HDMI I / F 74. Similarly, the control unit 65 is connected to the second HDMI terminal 23 via the second HDMI I / F 75. Accordingly, the control unit 65 can perform information transmission with each device connected to the second HDMI terminal 23 via the second HDMI I / F 75. Examples of devices connected to the HDMI terminals 22 and 23 include an AV amplifier, a DVD recorder, a DVD player, a PC, and a broadband router.

  The control unit 65 is connected to the USB terminal 24 via the USB I / F 76. Accordingly, the control unit 65 can perform information transmission with each device connected to the USB terminal 24 via the USB I / F 76. Examples of devices connected to the USB terminal 24 include a mobile phone, a digital camera, a card reader / writer, an HDD, and a keyboard.

  The control unit 65 is connected to the i. I. Via Link I / F77 Connected to the Link terminal 25. As a result, the control unit 65 makes i. Each device connected to the Link terminal 25, i. Information transmission can be performed via the Link I / F 77. i. Examples of devices connected to the Link terminal include AV-HDDs.

  The BS / CS digital broadcast receiving antenna 47 receives a satellite digital television broadcast signal and sends it to a satellite digital broadcast tuner 49 via an input terminal 48. The tuner 49 selects a broadcast signal of a channel selected by the user from the broadcast signal.

  A PSK (Phase Shift Keying) demodulator 50 demodulates the broadcast signal selected by the tuner 49 into a digital video signal and an audio signal, and outputs them to the signal processing unit 51.

  The terrestrial broadcast receiving antenna 52 receives a terrestrial digital television broadcast signal and a terrestrial analog television broadcast signal. The terrestrial digital television broadcast signal is sent to a terrestrial digital broadcast tuner 54 via an input terminal 53. The tuner 54 selects the broadcast signal of the channel selected by the user from this broadcast signal. An OFDM (Orthogonal Frequency Division Multiplexing) demodulator 55 demodulates the broadcast signal selected by the tuner 54 into a digital video signal and an audio signal, and outputs them to the signal processing unit 51.

  The terrestrial analog television broadcast signal is sent to the terrestrial analog broadcast tuner 56 via the input terminal 53. The tuner 56 selects a broadcast signal of a channel selected by the user from the broadcast signal. The analog demodulator 57 demodulates the broadcast signal selected by the tuner 56 into an analog video signal and an audio signal, and outputs them to the signal processing unit 51.

  The signal processing unit 51 performs predetermined digital signal processing on the digital video signal and the audio signal output from the PSK demodulator 50 or the OFDM demodulator 55, and applies the graphic processing unit 58 and the audio processing unit 59 to the graphic processing unit 58 and the audio processing unit 59. Output.

  The signal processing unit 51 is connected to a plurality of input terminals 60a, 60b, 60c, and 60d. These input terminals 60a to 60d can input an analog video signal and an audio signal from the outside to the digital television receiver 11, respectively.

  The signal processing unit 51 converts the analog video signal and audio signal output from the analog demodulator 57 or each of the input terminals 60a to 60d into a digital video signal and an audio signal. Next, the signal processing unit 51 performs predetermined digital signal processing on the digitized video signal and audio signal, and outputs them to the graphic processing unit 58 and the audio processing unit 59.

  The graphic processing unit 58 superimposes and outputs an OSD signal such as a menu generated by an OSD (On Screen Display) signal generation unit 61 on the digital video signal output from the signal processing unit 51. The graphic processing unit 58 can selectively output the video signal that is the output of the signal processing unit 51 and the OSD signal that is the output of the OSD signal generation unit 61.

  The digital video signal output from the graphic processing unit 58 is input to the video processing unit 62. The video processing unit 62 performs high image quality processing such as super-resolution conversion processing on the input digital video signal.

  FIG. 2 shows the configuration of the video processing unit 62. The video processing unit 62 includes an IP (Interrace / Progressive) conversion, an NR (Noise Reduction) process, a scaling unit 621, a super-resolution conversion processing unit 622, and a moving image improvement processing unit 623. The super-resolution conversion processing unit 622 performs a sharpening process for restoring the high-resolution image signal that is the second resolution by estimating the original pixel value from the low-resolution image signal that is the first resolution and increasing the number of pixels. I do. Here, the “original pixel value” is, for example, an image obtained when an image of the same subject as that obtained when a low resolution (first resolution) image signal is captured with a high resolution (second resolution) camera. A value indicated by each pixel of the signal. In addition, “estimate and increase the number of pixels” refers to capturing the characteristics of the target image, estimating the original pixel value from an image highly correlated within the same frame or between frames, and creating a new pixel. This means that the corresponding pixel value is used. That is, the correlation between images is used. Note that the super-resolution conversion processing unit 622 uses a publicly known / public technique disclosed in, for example, Japanese Unexamined Patent Application Publication No. 2007-310837, Japanese Unexamined Patent Application Publication No. 2008-98803, Japanese Unexamined Patent Application Publication No. 2000-188680, and the like. Is possible. As a technique of the super-resolution conversion processing unit 622 of the present embodiment, for example, a technique of restoring an image having a frequency component higher than the Nyquist frequency determined by the sampling period of the input image can be used.

  For example, in the case of using the super-resolution conversion process disclosed in Japanese Patent Application Laid-Open No. 2007-310837, a change in the pixel value in the target image area including the target pixel in the frame for each of a plurality of medium resolution frames. Select a plurality of corresponding points corresponding to a plurality of target image areas closest to the pattern from the reference frame, set the luminance sample value at the corresponding point to the pixel value of the target pixel corresponding to the corresponding point, Based on the size of the plurality of sample values and the arrangement of the plurality of corresponding points, the pixel value of the high-resolution frame corresponding to the reference frame, which is a high-resolution frame having a larger number of pixels than the reference frame, is calculated. Thus, the original pixel value is estimated from the low resolution image signal and the number of pixels is increased, thereby restoring the high resolution image signal.

  In addition, when using the super-resolution conversion process using self-congruent position search in the same frame image disclosed in Japanese Patent Application Laid-Open No. 2008-98803, the error of each pixel in the search area of the medium resolution frame is compared. And calculating a first pixel position that is minimum, and searching based on the first pixel position and the first error, the second pixel position around the first pixel, and the second error. The position where the error is minimum in the area is calculated with decimal precision. Then, a decimal precision vector with this position as the end point and the pixel of interest as the start point is calculated, and using the decimal precision vector, an extrapolated vector of the decimal precision vector with the pixel on the screen not included in the search area as the end point Is calculated. Then, based on the decimal precision vector, the extrapolation vector, and the pixel value acquired from the image signal, the pixel value of the high-resolution image having a larger number of pixels than the number of pixels included in the image signal is calculated. By performing such processing, the super-resolution conversion processing unit 622 restores the high-resolution image signal by estimating the original pixel value from the low-resolution image signal and increasing the number of pixels.

  Also, super-resolution conversion processing using mapping between a plurality of frame images disclosed in Japanese Patent Laid-Open No. 2000-188680 can be used.

  However, the method of super-resolution conversion processing in the super-resolution conversion processing unit 622 is not limited to the above, and high resolution can be obtained by estimating the original pixel value from the low-resolution image signal and increasing the number of pixels. Any method can be applied as long as the image signal is restored.

  The video processing unit 62 further converts the digital video signal that has been subjected to the super-resolution conversion processing into an analog video signal that has a format that can be displayed on the video display 14, and outputs the analog video signal to the video display 14. In addition, the video processing unit 62 derives an analog video signal to the outside via the output terminal 63. The video display 14 displays video based on the analog video signal output from the video processing unit 62.

  The audio processing unit 59 converts the input digital audio signal into an analog audio signal in a format that can be reproduced by the speaker 15, and outputs the analog audio signal to the speaker 15. The speaker 15 reproduces sound based on the analog sound signal. The audio processing unit 59 further derives an analog audio signal to the outside via the output terminal 64.

  FIG. 3 shows a block diagram when the video reproduction apparatus 91 is connected to the digital television receiver 11 of the present embodiment. Both the digital television receiver 11 and the video reproduction device 91 have a super-resolution function that is a function of executing a super-resolution conversion process on a video signal. For this reason, the video signal that has been subjected to the super-resolution conversion process in the video reproduction device 91 is input to the digital television receiver 11, and the super-resolution conversion process is again performed in the digital television receiver 11. In such a case, there is a possibility that the video quality is deteriorated due to noise or contours being too emphasized.

  The digital television receiver 11 according to the present embodiment performs control for executing the super-resolution conversion process only in either the digital television receiver 11 or the video playback device 91. Hereinafter, operations of the digital television receiver 11 and the video reproduction device 91 will be described with reference to FIG. The digital television receiver 11 is configured by the respective units shown in FIG. 1 described above. In FIG. 3, the digital television receiver 11 is connected to the video reproduction device 91 and operates when super-resolution conversion processing is controlled. The part is shown in a simplified manner.

  The digital television receiver 11 and the video reproduction device 91 are connected by, for example, an interface (hereinafter referred to as an HDMI interface) compliant with the HDMI (High Definition Multimedia Interface) standard. The HDMI interface performs video signal communication. The HDMI standard further defines the CEC (Consumer Electronics Control) standard. Therefore, the HDMI interface includes bidirectional communication means such as control information conforming to CEC.

  In FIG. 3, the digital television receiver 11 includes a signal input / output unit 811, a microcomputer 812, a video processing unit 62, and a video display 14.

  The signal input / output unit 811 controls communication with the video reproduction device 91. The signal input / output unit 811 receives the video signal and the control signal transmitted from the video reproduction device 91, and transmits the control signal to the video reproduction device 91. The signal input / output unit 811 sends the received video signal to the video processing unit 62 and a super-resolution control signal for turning on / off the super-resolution function to the microcomputer 812. The signal input / output unit 811 transmits the control signal sent from the microcomputer 812 to the video reproduction device 91.

  The microcomputer 812 transmits / receives a super-resolution control signal for turning on / off the super-resolution function for the video reproduction device 91 via the signal input / output unit 811. Further, the video processing unit 62 controls whether or not the super-resolution conversion processing unit 622 executes super-resolution of the video signal.

  The video processing unit 62 performs super-resolution by the super-resolution conversion processing unit 622 on the video signal sent from the signal input / output unit 811 according to control by the microcomputer 812. That is, when the super-resolution control signal for turning on the super-resolution conversion processing unit 622 is sent from the microcomputer 812, the super-resolution conversion process for the video signal is executed. On the other hand, when the super-resolution control signal for turning off the super-resolution conversion processing unit 622 is sent by the microcomputer 812, the super-resolution conversion process for the video signal is not executed.

  The video display 14 displays the video signal output from the video processing unit 62 on the screen.

  Next, the video playback device 91 is, for example, a DVD player or a set top box. The video playback device 91 includes a storage device 916, an interface 915, a microcomputer 912, a video processing unit 913, and a signal input / output unit 911. The super resolution conversion processing unit 914 performs the same processing as the super resolution conversion processing unit 622.

  The storage device 916 is a DVD or hard disk drive that stores video signals to be played back by the video playback device 91. The storage device 916 sends the video signal stored through the interface 915. When the storage device is a DVD, the DVD drive is an interface. When the storage device is a hard disk drive, the hard disk controller is an interface.

  The microcomputer 912 transmits and receives control signals to and from the digital television receiver 11 via the signal input / output unit 911. Further, the video processing unit 913 controls whether or not the super-resolution conversion processing unit 914 executes super-resolution of the video signal.

  The video processing unit 913 performs super-resolution conversion processing by the super-resolution conversion processing unit 914 on the video signal transmitted from the storage device 916 via the interface 915 under the control of the microcomputer 912. That is, when the super-resolution control signal for turning on the super-resolution conversion processing unit 914 is sent from the microcomputer 912, the super-resolution conversion process for the video signal is executed. On the other hand, when a super-resolution control signal for turning off the super-resolution conversion processing unit 914 is sent from the microcomputer 912, the super-resolution conversion process for the video signal is not executed.

  The signal input / output unit 911 controls communication with the digital television receiver 11. The signal input / output unit 911 receives a control signal transmitted from the digital television receiver 11 and transmits a video signal and a control signal to the digital television receiver 11. The signal input / output unit 911 sends a super-resolution control signal for turning on / off the super-resolution function to the microcomputer 912. Further, the signal input / output unit 911 transmits the super-resolution control signal sent from the microcomputer 912 to the digital television receiver 11.

  In the above description, when the super-resolution function in the super-resolution conversion processing unit 622 is turned on or off by the microcomputer 812, and the super-resolution function in the super-resolution conversion processing unit 914 is turned on by the microcomputer 912. Or the case of turning off was shown. When the super-resolution function is turned off in these operations, the super-resolution conversion processing unit 622 and the super-resolution conversion processing unit 914 having the super-resolution function do not perform the super-resolution conversion process. Specifically, the super-resolution conversion processing unit 622 and the super-resolution conversion processing unit 914 do not pass the video signal (hard through), or pass the video signal, but the parameter setting of the super-resolution conversion processing is effective. No setting (soft through). That is, when the super-resolution function is turned off, no video signal is input to the super-resolution conversion processing unit 622 and the super-resolution conversion processing unit 914, or the super-resolution conversion processing unit 622 and the super-resolution conversion processing unit. This is realized by either inputting the video signal to 914 but setting the parameter setting of the super-resolution conversion processing to an ineffective setting (setting the sharpening gain to zero without raising the sharpening gain or performing the restoration processing). . In the soft-through, the super-resolution conversion process may be executed by setting the parameter not to zero but weaker than usual so that the video signal is not adversely affected.

  Hereinafter, an operation when the digital television receiver 11 and the video reproduction device 91 are connected will be described.

  When the signal input / output unit 811 of the digital television receiver 11 and the signal input / output unit 911 of the video reproduction device 91 are connected via HDMI or the like, the digital television receiver 11 is connected to the video reproduction device 91. Detect that. In addition, the video reproduction device 91 detects that the digital television receiver 11 is connected.

  Next, the microcomputer 812 of the digital television receiver 11 and the microcomputer 912 of the video reproduction device 91 notify the other device of the presence or absence of the super-resolution function in each device. For this notification, for example, as described above, a bidirectional communication unit conforming to HDMI-CEC is used. This notification is sent to the digital television receiver as a control signal for inquiring whether or not there is a super-resolution function transmitted from the video reproduction device 91 after the connection between the digital television receiver 11 and the video reproduction device 91 is detected. 11 or after the video reproduction apparatus 91 receives a control signal for inquiring about the presence or absence of the super-resolution function transmitted from the digital television receiver 11.

  Based on this notification, the digital television receiver 11 executes the super-resolution conversion process only in one of the digital television receiver 11 and the video reproduction device 91 when the video reproduction device 91 also has a super-resolution function. To control. That is, when the super resolution conversion processing by the super resolution conversion processing unit 622 is executed in the digital television receiver 11, the video replay device 91 turns off the super resolution conversion processing unit 914 and performs the super resolution conversion processing. Do not execute. On the other hand, when super-resolution conversion processing by the super-resolution conversion processing unit 914 is executed in the video reproduction device 91, the digital television receiver 11 turns off the super-resolution conversion processing unit 622 and performs super-resolution conversion processing. Do not execute.

  4 and 5, both the digital television receiver 11 and the video reproduction device 91 have the super-resolution conversion function, but the operation when the super-resolution conversion process is executed only by the digital television receiver 11. It is a flowchart which shows an example.

  FIG. 4 shows an operation when the digital television receiver 11 first notifies the video playback device 91 that the digital television receiver 11 has a super-resolution function.

  When the digital television receiver 11 and the video reproduction device 91 are connected and two-way communication between the devices becomes possible, the digital television receiver 11 is more than the video reproduction device 91. A notification indicating that a resolution function is provided is transmitted (step S101). Receiving this notification, the video reproduction device 91 turns off the super-resolution function by the microcomputer 912 (step S102). That is, the microcomputer 912 turns off the super resolution conversion processing unit 914. Then, the digital television receiver 11 displays to the user that the super-resolution function of the video playback device 91 is turned off by using the GUI (step S103).

  Note that the notification of having the super-resolution function in step S101 is not automatically sent from the digital television receiver 11 to the video playback device 91, but the presence / absence of the super-resolution function transmitted from the video playback device 91. It may be after the digital television receiver 11 has received a control signal for inquiring.

  In the operation illustrated in FIG. 4, the video reproduction device 91 that has received the notification that the digital television receiver 11 has the super-resolution function executes processing for turning off the super-resolution function of the video reproduction device 91. This needs to be set in advance for the video playback device 91.

  In the operation shown in FIG. 4, the notification is first given from the digital television receiver 11 to the video reproduction device 91, whereas in FIG. 5, the video reproduction device 91 sends the notification to the digital television receiver 11. An operation in the case where the video playback device 91 performs notification that the super-resolution function is provided will be described.

  When the digital television receiver 11 and the video playback device 91 are connected and bidirectional communication between the devices is possible, the video playback device 91 is super-resolution with respect to the digital television receiver 11. A notification to the effect is transmitted (step S201). Receiving this notification, the digital television receiver 11 determines whether or not the super-resolution function of the digital television receiver 11 is turned on by the microcomputer 812 (step S202). When the super-resolution function of the digital television receiver 11 is off (OFF in step S202), the microcomputer 812 turns on the super-resolution function of the digital television receiver 11 (step S203). That is, the microcomputer 812 turns on the super resolution conversion processing unit 622. Note that the microcomputer 812 may turn on the super-resolution conversion processing unit 622 in accordance with a user operation.

  If the super-resolution function of the digital television receiver 11 is on (ON in step S202), or if the super-resolution function of the digital television receiver 11 is turned on in step S203, the digital television receiver 11 transmits a command for turning off the super-resolution function of the video playback device 91 to the video playback device 91 (step S204). The video reproduction device 91 that has received this command turns off the super-resolution function of the video reproduction device 91 by the microcomputer 912 (step S205). That is, the microcomputer 912 turns off the super resolution conversion processing unit 914. Then, the digital television receiver 11 displays to the user that the super-resolution function of the video playback device 91 is turned off by using the GUI (step S206).

  Note that the notification of having the super-resolution function in step S201 is not automatically transmitted from the video reproduction apparatus 91 to the digital television receiver 11, but is transmitted from the digital television receiver 11. It may be after the video reproduction apparatus 91 receives a control signal for inquiring whether or not there is.

  By the operation shown in FIG. 4 or FIG. 5, the digital television receiver 11 displays an image that has been subjected to super-resolution conversion processing only in the digital television receiver 11. In other words, it is possible to avoid double super-resolution conversion processing on the video, and to prevent degradation of the video quality. In addition, the above operation is automatically performed when the connection between the digital television receiver 11 and the video reproduction device 91 is detected. Therefore, the user turns off the super-resolution function of any device. Manual operation is not required.

  The operation examples shown in FIG. 4 and FIG. 5 can be appropriately selected and applied based on the actual device configuration, usage form, and the like. Also, in the operation examples shown in FIG. 4 and FIG. 5, the super-resolution conversion process is performed twice on the video signal by turning off the super-resolution capability in the video playback device 91. Although avoided, turning off the super-resolution function in the digital television receiver 11 may avoid double super-resolution conversion processing on the video. For example, the digital television receiver 11 receives a notification from the video playback device 91 that the video playback device 91 has a super-resolution function, and turns off the super-resolution function of the digital television receiver 11. It is realized by doing.

  As described above, in the present embodiment, when both the video display device and the video playback device have a video signal super-resolution function, super-resolution is performed only on either the video display device or the video playback device. Control for implementing the digitization process is performed. This control notifies the video playback device that the video display device has the super-resolution function, the video playback device turns off the super-resolution function, or the video display device plays the video. This is done by transmitting a control signal for turning off the super-resolution function to the apparatus. As a result, it is possible to prevent the video displayed on the video display device from being subjected to the super-resolution conversion process twice by the video display device and the video playback device, and to prevent deterioration of the video quality. .

  Further, the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

  DESCRIPTION OF SYMBOLS 11 ... Digital television receiver, 14 ... Video display device, 62 ... Video processing part, 622 ... Super-resolution conversion processing part, 811 ... Signal input / output part, 812 ... Microcomputer, 91 ... Video reproduction apparatus, 911 ... Signal input Output unit, 912... Microcomputer, 913... Image processing unit, 914 .. super-resolution conversion processing unit, 915... Interface, 916.

Claims (12)

Video receiving means for receiving a sharpened video signal from an external video playback device;
Image quality processing means for performing image quality processing including sharpening processing on the video signal;
Compared with a case where the sharpening process is not included in the image quality processing, a signal transmission means for transmitting a signal for weakening the effect of the sharpening process of the external video reproduction device to the external video reproduction device. A video display device characterized by that.   2. The video display device according to claim 1, wherein the signal transmission means transmits the signal in response to the connection of the external video reproduction device. Video receiving means for receiving a video signal from an external video playback device;
Image quality processing means for performing image quality processing including sharpening processing on the video signal;
Information receiving means for receiving information indicating whether or not the external video reproduction device has a function of executing a sharpening process;
When the information indicates that the external video playback device has a function of executing the sharpening process, the external video playback device sharpening process compared to when the image quality process does not include the sharpening process. A video display device comprising: signal transmission means for transmitting a signal for reducing the effect of the above to the external video reproduction device.   4. The video display device according to claim 3, wherein the information receiving means receives the information in response to the connection of the external video playback device.   The video display device according to claim 3, wherein the signal transmission unit transmits the signal in response to receiving the information.   The sharpening process includes a super-resolution conversion process that restores a video signal having a second resolution higher than the first resolution by estimating and increasing an original pixel value of the video signal having the first resolution. The video display device according to claim 1 or 3, characterized in that Sharpening means for sharpening the video signal;
Video signal transmission means for transmitting the sharpened video signal to an external video display device;
When the external video display device has a function of executing the sharpening process, the effect of the sharpening process by the sharpening means is greater than when the external video display device does not have the function of executing the sharpening process. And a control means for controlling to weaken the video reproducing apparatus. Further comprising information receiving means for receiving information indicating whether the external video display device has a function of executing the sharpening process;
The control means, when the information indicates that the external video display device has a function of executing the sharpening process, compared to when the external video display device does not have a function of executing the sharpening process. The video reproduction apparatus according to claim 7, wherein control is performed so as to weaken an effect of a sharpening process performed by the sharpening means. Compared with the case where the external video display device does not have the function of executing the sharpening process, the apparatus further comprises a signal receiving means for receiving a signal for weakening the effect of the sharpening process by the sharpening means,
8. The video reproduction apparatus according to claim 7, wherein the control means controls so as to weaken an effect of a sharpening process by the sharpening means in response to receiving the signal. Receiving a sharpened video signal from an external video playback device;
Performing image quality processing including sharpening processing on the video signal;
Transmitting to the external video playback device a signal for weakening the effect of the sharpening processing of the external video playback device as compared to when the sharpening processing is not included in the image quality processing. Characteristic video display method. Receiving a video signal from an external video playback device;
Performing image quality processing including sharpening processing on the video signal;
Receiving information indicating whether or not the external video reproduction device has a function of executing a sharpening process;
When the information indicates that the external video playback device has a function of executing the sharpening process, the external video playback device sharpening process compared to when the image quality process does not include the sharpening process. Transmitting a signal for weakening the effect to the external video reproduction device. Applying a sharpening process to the video signal;
Transmitting the sharpened video signal to an external video display device;
When the external video display device has a function of executing the sharpening process, the effect of the sharpening process of the external video playback device is greater than when the external video display device does not have the function of executing the sharpening process. And controlling to weaken the image.

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