JP6694280B2 - Video signal transmitting device, video signal receiving device, and video signal transmitting / receiving system - Google Patents

Description

  The present invention relates to a video signal transmitting device that transmits a hierarchical video signal in which an original image is hierarchized, a video signal receiving device that receives the video signal, and a video signal transmitting / receiving system that transmits / receives the video signal.

  2. Description of the Related Art Conventionally, in order to view clearer images, the resolution of image devices has been increased. 2K video is generally used for television broadcasting, and its resolution is 1920 × 1080. In addition, a television broadcast of a 4K video having a double resolution in the horizontal direction and a 8K video having a double resolution in the vertical direction is planned. The resolution of 4K video is 3840 × 2160, and the resolution of 8K video is 7680 × 4320.

  On the other hand, the HD-SDI signal system has become widespread as an interface for transmitting video signals and connecting devices such as cameras and monitors. However, it is insufficient to transmit the 4K video signal and the 8K video signal by the HD-SDI signal system, and it is necessary to newly define a high speed signal system.

  As one of the candidates, it is possible to use Ethernet (registered trademark). By using Ethernet, the video signal can be packetized according to the widely used IP protocol. High-speed transmission of 100 Gbps has already been realized by enabling multiplexing and routing of video signals.

  With the increase in resolution of captured video, a wider line band is required to transmit video signals. When a band for transmitting a high-resolution image cannot be secured, it has been reported that a JPEG2000 hierarchical encoding method is used to receive only a lower-resolution image and reproduce the original image signal (non- See Patent Document 1).

  Further, in order to easily acquire a video with a desired resolution, a method of acquiring an image in a format according to the JPEG2000 hierarchical encoding method from a server has been proposed (see Patent Document 1).

  FIG. 39 is a schematic diagram showing an example of the overall configuration of a conventional video signal transmitting / receiving system. The video signal transmission / reception system includes a video signal transmission device 101, a distributor 102, down converters 103-1 and 103-2, a router 104, and video signal reception devices 105-1 to 105-3.

  This video signal transmitting / receiving system includes three video signal receiving devices 105-1 to 105-3. When these video signal receiving devices 105-1 to 105-3 are, for example, monitors, the resolution of the required video signal differs depending on the size of the monitor, the displayable resolution, and the like. Here, the video signal receiving device 105-1 is a monitor for high resolution, the video signal receiving device 105-2 is a monitor for medium resolution, and the video signal receiving device 105-3 is a monitor for low resolution. And

  The video signal transmission device 101 is, for example, a camera, generates a high resolution video signal, and transmits the high resolution video signal to the distributor 102. The distributor 102 receives the high resolution video signal from the video signal transmission device 101 and distributes the high resolution video signal to the router 104 and the down converters 103-1 and 103-2, respectively.

  The down converter 103-1 receives the high-resolution video signal distributed by the distributor 102, down-converts the high-resolution video signal to generate a medium-resolution video signal, and transmits the medium-resolution video signal to the router 104. To do. The down converter 103-2 receives the high resolution video signal distributed by the distributor 102, down-converts the high resolution video signal to generate a low resolution video signal, and transmits the low resolution video signal to the router 104. To do.

  Thereby, a video signal suitable for the video signal receiving devices 105-1 to 105-3 having different display capabilities from high resolution to low resolution is generated and transmitted to the router 104.

  The router 104 is provided especially in the case of a large-scale video signal transmission / reception system and constitutes a matrix switch. The router 104 receives the high resolution video signal from the distributor 102, the medium resolution video signal from the down converter 103-1 and the low resolution video signal from the down converter 103-2. Then, the router 104 switches the received high-resolution video signal, medium-resolution video signal, and low-resolution video signal so that the video signal receiving devices 105-1 to 105-3 can receive the video signal of a desired resolution. The router 104 transmits the high resolution video signal to the video signal receiving device 105-1, the medium resolution video signal to the video signal receiving device 105-2, and the low resolution video signal to the video signal receiving device 105-3. To do.

  The video signal receiving device 105-1 receives the high resolution video signal from the router 104, performs reception processing on the high resolution video signal, and performs processing such as video display. Similarly, the video signal receiving device 105-2 receives the medium resolution video signal from the router 104, and the video signal receiving device 105-3 receives the low resolution video signal from the router 104 and performs reception processing, video display, and the like. Perform processing.

  As described above, in the video signal transmitting / receiving system shown in FIG. 39, three types of video signals having different resolutions are required for the same video. Therefore, different video signals are generated in advance by the down converters 103-1 and 103-2, and three different resolution video signals (high resolution video signal, medium resolution video signal and low resolution video signal) are transmitted to the router 104. To be done. Then, the router 104 transmits the video signal of the desired resolution to the video signal receiving devices 105-1 to 105-3.

Japanese Patent No. 5515758

"Successful demonstration of multi-point video conferencing using 4K ultra-high-definition video", [online], December 25, 2008, Keio University Digital Media and Content Research Institute, Nippon Telegraph and Telephone Corporation, [2015] Search on November 2], Internet <http: // www. keio. ac. jp / ja / press_release / 2008 / kr7a43000000maf6-att / 081225_2. pdf>

  In consideration of editing and combining of images in order to produce an image program, it is desirable to transmit while maintaining the image signal value (original signal) at the time of shooting. Further, in order to produce a live broadcast program, it is desirable to transmit in real time without causing a transmission delay. That is, it is required to transmit a video signal without compression, or to perform reversible high-speed compression encoding without performing compression encoding to remove high frequency components from the original signal.

  Also, when transmitting a video signal using Ethernet, the video signal transmission speed is set to a video signal speed that can be kept within the upper limit of the Ethernet transmission speed already defined by standardization. It is desirable to carry the signal over multiple Ethernet lines. By this method, it is possible to avoid a situation where the system is complicated.

  However, the conventional method does not consider maintaining the original signal or realizing low-delay transmission. Further, it is not considered that the already standardized video signal format is accommodated within the speed of the separately standardized Ethernet transmission system to realize the transmission within one line. Further, in order to provide a video signal with a plurality of resolutions corresponding to the receiving side, it is necessary for the transmitting side to generate a video signal with a plurality of resolutions in advance and input it to the matrix switch. Increasing the input bit rate was unavoidable.

  Therefore, the present invention has been made to solve the above problems, and an object thereof is to transmit a video signal having a resolution according to the receiving side, maintain the accuracy of the original video signal, and perform low-delay transmission. An object is to provide a video signal transmitting device, a video signal receiving device, and a video signal transmitting / receiving system that are realized.

In order to solve the above problems, the video signal transmitting apparatus according to claim 1 converts RGB values in a 12-bit unit 8K original image operating at 120 Hz into YUV values and outputs YUV 4: 4: 4 format signals as 8K. A wavelet 5-3 reversible in the horizontal direction based on an RGB / YUV conversion unit generated as a YUV layer image and an 8K-UV layer image of the 8K-YUV layer images generated by the RGB / YUV conversion unit. 5-3 conversion according to the conversion method is performed, and 8K-UV (hL1 (h indicates that 5-3 conversion in the horizontal direction is performed, L indicates that a low-pass filter is applied)) layer. The 8K-YUV hierarchical image generated by the RGB / YUV conversion unit, which is a YUV 4: 2: 2 format signal, and a first 5-3 conversion unit that generates an image. Of the 8K-Y layer image and the 8K-UV (hL1) layer image generated by the first 5-3 conversion unit, a 120 Hz frame for 120 Hz, a 60 and 120 Hz frame common to 60 Hz and 120 Hz, and The frame classification unit for classifying 30, 60, and 120 Hz frames commonly used for 30 Hz, 60 Hz, and 120 Hz, the 120 Hz frame processing unit, the 60, 120 Hz frame processing unit, and the 30, 60, 120 Hz frame processing unit, and the 120 Hz frame A first header adding unit that adds distinction information to a header for the 8K-Y hierarchical image and the 8K-UV (hL1) hierarchical image in the 120 Hz frame classified by the frame classification unit; The header is added by the first header adding unit. A first packet transmitting unit that generates a packet of each layer image and transmits the packet as an uncompressed layer video signal, and the 60 and 120 Hz frame processing units are classified by the frame classifying unit. Further, upper 10-bit data and lower 2-bit data are separated from the 12-bit data of the 8K-Y hierarchical image and the 8K-UV (hL1) hierarchical image in the 60, 120 Hz frame, and the upper 10-bit data is separated from the upper 10-bit data. A first data separation unit that generates an 8K-Y hierarchical image and an 8K-UV (hL1) hierarchical image corresponding to 8K video in 10-bit units, and that generates the lower 2 bits of data as 12-bit data. , based on the first of the 8K-Y layer image generated by the data component away portion, by the 5-3 conversion, 10 4K-Y (hH1 (H indicates that a high-pass filter is applied) corresponding to a 4K video in bit units. ), VH1 (v indicates that 5-3 conversion in the vertical direction is performed.), VL1) a second 5-3 conversion unit for generating a layer image, generated by the first data content away section The 5-3 conversion and the YUV value conversion are performed based on the 8K-UV (hL1) layered image thus generated to generate a 4K-UV (hH2, vH2, vL2) layered image corresponding to a 4K video in 10-bit units. third and 5-3 conversion section, the first of the 12-bit data generated by the data component away portion, the second of the 4K-Y generated by the 5-3 conversion unit (hH1 that, VH1 , VL1) hierarchical image and the 4K-UV (hH2, vH2, vL2) hierarchical image generated by the third 5-3 conversion unit, a second header addition unit that adds discrimination information to the header. By the second header addition unit A second packet transmitting unit that generates a packet of the 12-bit data with a header and each layer image, and transmits the packet as an uncompressed layer video signal. A frame processing unit, from the 12-bit data of the 8K-Y hierarchical image and the 8K-UV (hL1) hierarchical image in the 30, 60, and 120 Hz frames classified by the frame classification unit, upper 10-bit data and lower 2 Bit data is separated, the lower 2 bits of data are generated as 12-bit data, upper 8 bits of data and lower 2 bits of data are separated from the upper 10 bits of data, and the lower 2 bits of data are separated. Is generated as 10-bit data, and 8 bits in units of 8 bits are formed from the upper 8-bit data. Based on the 8K-Y layer image and 8K-UV (hL1) and second data separating unit that generates a layer image, wherein the second of said 8K-Y layer image generated by the data content away portion corresponding to the picture By the 5-3 conversion, a 4K-Y (hH1, vH1) hierarchical image corresponding to 4K video in 8-bit units and a 2K-Y (hH2, vH2, vL2) corresponding to 2K video in 8-bit units are generated. the fourth and 5-3 conversion unit, based on the generated the 8K-UV (hL1) layer image by the second data component away section performs the 5-3 conversion and YUV value conversion, 8 bits Fifth 5-3 conversion for generating a 4K-UV (hH2, vH2) layer image corresponding to a unit 4K image and a 2K-UV (hH3, vH3, vL3) layer image corresponding to an 8-bit unit 2K image Part and the second Of said generated by the data content away portion 12-bit data and the 10-bit data, the fourth of the 4K-Y generated by the 5-3 conversion unit (hH1, VH1) hierarchical image and the 2K-Y (HH2, vH2, vL2), and the 4K-UV (hH2, vH2) layer image and the 2K-UV (hH3, vH3, vL3) layer image generated by the fifth 5-3 conversion unit are distinguished. A third header addition unit for adding information to the header, and a packet of the 12-bit data, the 10-bit data and the respective layer images to which the header is added by the third header addition unit, A third packet transmitting section for transmitting the packet as an uncompressed hierarchical video signal, and the first packet transmitting section of the 120 Hz frame processing section. An original image of 8K video is reproduced in the packet transmitted by the second packet transmission unit of the 60, 120 Hz frame processing unit and the third packet transmission unit of the 30, 60, 120 Hz frame processing unit. For example, a packet transmitted using 100 Gbps Ethernet in order to reproduce 4K video, a packet transmitted using 10 Gbps Ethernet in order to reproduce 4K video, and a packet transmitted using 1 Gbps Ethernet in order to reproduce 2K video. It is included.

The video signal transmitting device according to claim 2 performs 5-3 conversion according to the wavelet 5-3 reversible conversion method on the basis of an 8K original image in 12-bit units operating at 120 Hz, and outputs 120 Hz hH1 (h). Indicates that the horizontal 5-3 conversion has been performed, H indicates that the high-pass filter has been applied, vH1 (v indicates that the vertical 5-3 conversion has been applied). , VL1 (L indicates that a low-pass filter has been applied.) First 5-3 conversion unit for generating a hierarchical image, and the 120 Hz vL1 hierarchical image generated by the first 5-3 conversion unit. And a first time direction 5-3 conversion unit that performs the 5-3 conversion in the time direction based on the above to generate a 60 Hz vL1-H, L layer image, and the first time direction 5-3 conversion unit. 60 Hz v generated by Generated by a second 5-3 conversion unit that performs the 5-3 conversion based on the 1-L hierarchical image and generates a 60 Hz hH2, vH2, vL2 hierarchical image, and the second 5-3 conversion unit. A second time direction 5-3 conversion unit that performs the 5-3 conversion in the time direction based on the 60 Hz vL2 hierarchical image and generates a 30 Hz vL2-H, L hierarchy image; 5-3 conversion of the 120Hz generated by unit hH1, VH1 layer image, the first of the 60Hz generated by the time direction 5-3 conversion unit vL1-H layer image, the second 5-3 the 60Hz generated by varying section HH2, VH2 layer image, and the second of the 30Hz generated by the time direction 5-3 conversion section VL2-H, the L layer image, adding identification information to the header Header And a packet transmitting unit that generates a packet of each layer image to which the header is added by the header adding unit and transmits the packet as an uncompressed layer video signal. ..

The video signal receiving apparatus according to claim 3, to the router to forward packets sent from the video signal transmitter according to claim 1, a packet requesting unit for transmitting a transmission request for obtaining a desired hierarchical images, The 1 Gbps Ethernet is used to reproduce 2K video, the 10 Gbps Ethernet is used to reproduce 4K video, and the 100 Gbps Ethernet is used to reproduce the original 8K video image. A corresponding packet is received from the router, a packet receiving unit that distinguishes 12-bit data, 10-bit data, and a hierarchical image based on the identification information added to the header of the packet; The first video reproduction unit reproduces the 4K video, the second video reproduction unit reproduces the 4K video, and the third video reproduction unit reproduces the 8K original image. At least one or more video reproducing units, and the first video reproducing unit is a 2K-Y (vL2) hierarchical image and 2K-UV (30, 60, 120 Hz frame images distinguished by the packet receiving unit. A vL3) layer image is extracted, and a 2K-Y (vL2) layer image and a 2K-UV (vL3) layer image are output as a video signal of an 8K unit 2K image operating at 30 Hz. The second video reproduction unit follows the wavelet 5-3 reversible conversion method based on the 2K-Y (hH2, vH2, vL2) layer image of the 30, 60, and 120 Hz frames distinguished by the packet reception unit. 5-3 Inverse conversion is performed to reproduce a 4K-Y (vL1) layer image of 30, 60, 120 Hz frames, and 30, 6 discriminated by the packet receiving unit. , 60 Hz, 120 Hz frame 4K-UV (vL2) layer image is reproduced by the 5-3 inverse transformation based on the 120 Hz frame 2K-UV (hH3, vH3, vL3) layer image, and the 30, 60 , 120 Hz frame 4K-Y (vL1) layer image and 4K-UV (vL2) layer image with the 10-bit data added, and the 10-bit data added with the 30, 60, 120 Hz frame 4K-Y. The (vL1) layer image and the 4K-UV (vL2) layer image, and the 4K-Y (vL1) layer image and the 4K-UV (vL2) layer image of the 60 and 120 Hz frames distinguished by the packet receiving unit are set to 60 Hz. And a 5-3 inverse conversion and 10-bit restoration unit for outputting as a video signal of 4K video in 10-bit units, The third video reproducing unit is reproduced by the 4K-Y (hH1, vH1) layer image of the 30, 60, and 120 Hz frames distinguished by the packet receiving unit, and the 5-3 inverse conversion and 10-bit restoring unit. On the basis of the 4K-Y (vL1) layer image of the 30, 60, 120 Hz frame, the 8K-Y layer image of the 30, 60, 120 Hz frame is reproduced by the 5-3 inverse transformation, and the 8K-Y layer is reproduced. The 10-bit data and the 12-bit data are added to the image, and the 4K-UV (hH2, vH2) layer image of 30, 60, and 120 Hz frames distinguished by the packet receiving unit, and the 5-3 reverse. The 5-3 reverse based on the 4K-UV (vL2) layer image of the 30, 60 and 120 Hz frames reproduced by the conversion and 10-bit restoration unit. As a result, the 8K-UV hierarchical image of 30, 60, and 120 Hz frames is reproduced, the 10-bit data and the 12-bit data are added to the 8K-UV hierarchical image, and the packet is discriminated by the packet receiving unit. , 120 Hz frame 4K-Y (hH1, vH1, vL1) layer image is reproduced by the 5-3 inverse transform, and 60, 120 Hz frame 8K-Y layer image is reproduced. Based on the 4K-UV (hH2, vH2, vL2) layer image of the 60 and 120 Hz frames which are added with 12-bit data and are distinguished by the packet receiving unit, the 5 and 3 reverse conversion is performed to convert the 60 and 120 Hz frames. The 8K-UV layer image is reproduced, the 12-bit data is added to the 8K-UV layer image, and the packet receiving unit Based on the more distinguished 120 Hz frame 8K-UV (hL1) layer image, the 5-3 inverse conversion reproduces the 120 Hz frame 8K-UV layer image, and the 10-bit data and the 12-bit data are reproduced. 8K-YUV hierarchical image of the 30, 60, 120 Hz frame added with, the 8K-YUV hierarchical image of the 60, 120 Hz frame added with the 12-bit data, and of the 120 Hz frame distinguished by the packet receiving unit. An 8K-Y hierarchical image and the reproduced 8K-UV hierarchical image of the 120 Hz frame are output as a video signal of an 8K video in 12-bit units operating at 120 Hz, and a 5-3 reverse conversion and 12-bit restoration unit is provided. Characterize.

The video signal receiving device according to claim 4 is the video signal receiving device in a video signal transmitting / receiving system including a video signal transmitting device, a router, and a video signal receiving device. The device performs 5-3 conversion according to the wavelet 5-3 reversible conversion method on the basis of an 8K original image in 12-bit units operating at 120 Hz, and outputs RGB signals RGB (hH1 (h is 5 in the horizontal direction). -3 is applied, H indicates that a high-pass filter is applied, vH1 (v indicates that 5-3 conversion in the vertical direction is applied), vL1 (L indicates L). It indicates that a low-pass filter has been applied.)) Based on a first 5-3 conversion unit that generates a hierarchical image and the RGB (vL1) hierarchical image generated by the first 5-3 conversion unit. , The above A second 5-3 conversion unit that performs -3 conversion to generate an RGB (hH2, vH2, vL2) layer image, and the RGB (hH1, vH1) layer generated by the first 5-3 conversion unit For the image and the RGB (hH2, vH2, vL2) layer image generated by the second 5-3 conversion unit, a header addition unit that adds distinction information to the header, and the header is added by the header addition unit. And a packet transmitter for generating packets of the RGB (hH1, vH1) layer image and RGB (hH2, vH2, vL2) layer image and transmitting these packets as an uncompressed layer video signal, the video signal receiving device, to the router to forward packets sent from the video signal transmitter, to transmit a transmission request for obtaining a desired hierarchical image A packet request unit, a packet reception unit that receives a packet corresponding to the transmission request from the router, and distinguishes a hierarchical image based on the distinction information added to the header of the packet, and reproduces an original image of 8K video A first video reproduction unit for reproducing 4K video, and a video reproduction unit for at least one of a third video reproduction unit for reproducing 2K video. Of the RGB (hH2, vH2, vL2) layered image discriminated by the packet receiving unit, performs the 5-3 inverse transformation according to the wavelet 5-3 reversible transformation method, and RGB (vL1) The hierarchical image is reproduced, the 5-3 inverse conversion is performed based on the RGB (hH1, vH1) hierarchical image and the RGB (vL1) hierarchical image which are distinguished by the packet receiving unit, and the original image is generated. A first 5-3 inverse conversion unit which reproduces an image and outputs the original image as a video signal of a 12-bit unit 8K video operating at 120 Hz is provided, and the second video reproduction unit receives the packet. A second 5-3 inverse transformation unit that performs the 5-3 inverse transformation based on the RGB (hH2, vH2, vL2) hierarchical image that is distinguished by a unit, and reproduces an RGB (vL1) hierarchical image; The RGB (vL1) hierarchical image reproduced by the 5-3 conversion unit 2 is converted into a color signal of RGB 12-bit color depth into RGB 10-bit color depth for a video signal of 12-bit unit 4K video operating at 120 Hz. Then, a 12/10 RGB color gamut conversion unit that generates a video signal of a 10-bit unit 4K video that operates at 120 Hz, and the 120 generated by the 12/10 RGB color gamut conversion unit. YUV4: 2: 2 converter for converting RGB values into YUV values in YUV4: 2: 2 format, and YUV4: 2: 2 converter for YUV4: Regarding the video signal of 4K video in 10-bit unit operating at 120Hz converted to YUV value in 2: 2 format, the video signal of 4K video in 10-bit unit operating at 60Hz by converting the frame rate from 120Hz to 60Hz. And a first frame rate conversion unit for outputting a 2K image in 12-bit units operating at 120 Hz, which is an RGB (vL2) hierarchical image distinguished by the packet receiving unit. For the video signal of, the color gamut conversion from the RGB 12-bit color depth to the RGB 8-bit color depth is performed at 120 Hz. A 12/8 RGB color gamut conversion unit that generates an 8-bit unit 2K video signal, and an 8-bit unit 2K video signal that operates at 120 Hz and that is generated by the 12/8 RGB color gamut conversion unit , A YUV4: 0: 0 conversion unit for converting RGB values into YUV values in the YUV4: 0: 0 format, and 120 Hz converted into YUV values in the YUV4: 0: 0 format by the YUV4: 0: 0 conversion unit. A second frame rate conversion unit for converting the video signal of the 2K video in 8-bit units operating, the frame rate from 120Hz to 30Hz, and outputting the video signal of the 2K video in 8-bit units operating at 30Hz. It is characterized by

The video signal receiving device according to claim 5 further includes a packet request unit that transmits a transmission request for acquiring a desired hierarchical image to a router that transfers the packet transmitted from the video signal transmitting device according to claim 2 . A packet receiving unit that receives a packet corresponding to the transmission request from the router and that distinguishes a hierarchical image based on the identification information added to the header of the packet, and a first image that reproduces an 8K image of the original image. A playback unit, a second video playback unit that plays back 4K video, and at least one video playback unit out of a third video playback unit that plays back 2K video, wherein the first video playback unit is , The 5L inverse transform in accordance with the wavelet 5-3 reversible transform method is applied in the time direction based on the 30Hz vL2-H, L layer images distinguished by the packet receiving unit, and the 60Hz vL2. It is generated by a first time direction 5-3 inverse conversion unit for reproducing a layer image, a 60 Hz hH2, vH2 hierarchical image distinguished by the packet reception unit, and the first time direction 5-3 inverse conversion unit. And a first 5-3 inverse transform unit for performing a 5-3 inverse transform according to a wavelet 5-3 lossless transform method based on the 60 Hz vL2 hierarchical image, and reproducing a 60 Hz vL1 hierarchical image, and the packet. Based on the 60 Hz vL1-H layer image distinguished by the receiving unit and the 60 Hz vL1 layer image reproduced by the first 5-3 inverse transform unit, the 5-3 inverse transform is performed in the time direction. , A second time direction 5-3 inverse transform unit for reproducing a vL1 layer image of 120 Hz, an hH1, vH1 layer image of 120 Hz distinguished by the packet receiving unit, and the second time. Based on the vL1 hierarchical image of 120 Hz generated by the direction 5-3 inverse conversion unit, the 5-3 inverse conversion is performed, the original image is reproduced, and the original image is operated in a 12-bit unit at 8 Hz in 8K. A second 5-3 inverse conversion section for outputting as an image signal of an image, wherein the second image reproduction section includes the first time direction 5-3 inverse conversion section and the first 5-side inverse conversion section. For the video signal of 4K video in 12-bit units operating at 60 Hz, which is the vL1 layer image of 60 Hz reproduced by the 3 inverse conversion section and the first 5-3 inverse conversion section, the RGB12-bit color depth is RGB10. A first color gamut conversion unit that converts the color gamut to a bit color depth and outputs a video signal of a 4K video in 10-bit units operating at 60 Hz, wherein the third video reproduction unit has the packet Distinguished by receiver For a video signal of a 2K video in 12-bit units operating at 120 Hz which is a vL2-L hierarchical image of 30 Hz, color gamut conversion of RGB 12-bit color depth into RGB 8-bit color depth is performed, and RGB values are converted into YUV 4: 0: 0 format. It is characterized by including a second color gamut etc. conversion unit for converting to YUV value of and outputting a video signal of 2K video of 8 bit unit operating at 30 Hz.

Furthermore, the video signal transmission and reception system according to claim 6, and movies image signal transmitting apparatus, a router and a first video signal receiving apparatus, the second video signal transmitting and receiving system including a video signal receiving apparatus Then, the video signal transmitting device performs 5-3 conversion in the horizontal direction according to the wavelet 5-3 reversible conversion method on the first layer based on an image of a predetermined resolution, and applies a high-pass filter. To generate a horizontal high-pass filter hierarchical image (hH) and a low-pass filter to generate a horizontal low-pass filter hierarchical image (hL), and perform the 5-3 conversion in the vertical direction based on the horizontal low-pass filter hierarchical image (hL). Vertical high pass filter hierarchical image (vH) by applying the high pass filter, and vertical low pass filter by applying the low pass filter. A layer image (vL) is generated, and for the n-th layer (n is an integer of 2 or more), based on the vertical low-pass filter layer image (vL) of the (n-1) -th layer, the 5 -3 conversion is performed to generate the horizontal high-pass filter hierarchical image (hH) and the horizontal low-pass filter hierarchical image (hL), and the 5-3 conversion is performed in the vertical direction based on the horizontal low-pass filter hierarchical image (hL). 5-3 conversion unit for generating the vertical high-pass filter hierarchical image (vH) and the vertical low-pass filter hierarchical image (vL), and the horizontal high-pass filter hierarchical image (hH) generated by the 5-3 conversion unit. ), A distinction for distinguishing each hierarchical image in the vertical high-pass filter hierarchical image (vH) and the vertical low-pass filter hierarchical image (vL) And a packet for generating a packet of each hierarchical image to which the header is added by the header adding unit and transmitting the packet of each hierarchical image as an uncompressed hierarchical video signal. A transmission unit, wherein the packet transmission unit transmits packets of the horizontal high-pass filter hierarchical image (hH) and the vertical high-pass filter hierarchical image (vH) for the first to (n-1) th hierarchical layers. and, for the n-th hierarchy, and transmits the packet of the horizontal high-pass filter layer image (hH), said vertical high-pass filter layer image (vH) and the vertical low-pass filter layer image (vL), the router, the video The packet transmitted from the signal transmitting device is received, and the transmission request from the first video signal receiving device is received. Of the received packets, a packet of a hierarchical image corresponding to the transmission request is transmitted to the first video signal receiving device, a transmission request is received from the second video signal receiving device, and the received packet is received. Among them, a packet of a hierarchical image according to the transmission request is transmitted to the second video signal receiving device, and the first video signal receiving device causes the horizontal high-pass filter hierarchical image (hH) and the vertical high-pass filter hierarchical image ( vH) and a vertical low-pass filter hierarchical image (vL), a first packet request unit for transmitting a transmission request to the router, and a packet corresponding to the transmission request from the router, and a header of the packet. Based on the discrimination information added to the first packet receiving unit that discriminates the hierarchical image, and the vertical high level discriminated by the first packet receiving unit. The horizontal low-pass filter hierarchical image (hL) is obtained by performing the 5-3 inverse transform in the vertical direction according to the wavelet 5-3 reversible transform method based on the vertical filter low-pass filter image (vH) and the vertical low-pass filter hierarchical image (vL). The 5-3 inverse transform is performed in the horizontal direction on the basis of the reproduced horizontal high-pass filter hierarchical image (hH) distinguished by the first packet receiving unit and the reproduced horizontal low-pass filter hierarchical image (hL). The vertical low-pass from the 5-3 inverse conversion unit that reproduces the image of the original predetermined resolution and outputs the image as a high-resolution video signal, and the hierarchical image that is distinguished by the first packet receiving unit. A first data extraction unit that extracts a filter hierarchy image (vL) and outputs the vertical low-pass filter hierarchy image (vL) as a low-resolution video signal. And a packet corresponding to the transmission request, wherein the second video signal reception device transmits a transmission request for acquiring the vertical low-pass filter hierarchical image (vL) to the router, and a packet corresponding to the transmission request. Is received from the router, and is distinguished by the second packet receiving unit that distinguishes the vertical low-pass filter hierarchical image (vL) based on the distinguishing information added to the header of the packet, and the second packet receiving unit. A second data extraction unit for extracting the vertical low-pass filter hierarchical image (vL) that has been generated and outputting the vertical low-pass filter hierarchical image (vL) as the low-resolution video signal. ..

  As described above, according to the present invention, it is possible to transmit a video signal having a resolution according to the receiving side, maintain the accuracy of the original video signal, and realize low-delay transmission.

It is a conceptual diagram explaining a wavelet 5-3 two-dimensional reversible conversion system. Wavelet 5-3 is a schematic diagram illustrating images before and after conversion by a two-dimensional reversible conversion method. It is a figure explaining a hierarchy image. 1 is a block diagram showing a configuration example of a video signal transmission device according to a first embodiment. 3 is a flowchart showing a processing example of the video signal transmission device according to the first embodiment. 1 is a block diagram showing a configuration example of a video signal receiving device according to a first embodiment. 3 is a flowchart showing a processing example of the video signal receiving device according to the first embodiment. 1 is a schematic diagram showing an example of the overall configuration of a video signal transmitting / receiving system according to Example 1. FIG. FIG. 9 is a block diagram showing a configuration example of a video signal transmission device according to a second embodiment. It is a block diagram which shows the structural example of a 120 Hz frame processing part. It is a block diagram which shows the structural example of a 60, 120 Hz frame processing part. It is a block diagram which shows the structural example of a 30, 60, 120-Hz frame processing part. 9 is a flowchart showing a processing example of the video signal transmission device according to the second embodiment. It is a flow chart which shows an example of 60 and 120 Hz frame processing (processing of Step S1305). It is a flow chart which shows an example of 30, 60, and 120 Hz frame processing (processing of Step S1306). FIG. 9 is a block diagram showing a configuration example of a first video signal receiving device according to a second embodiment. FIG. 9 is a block diagram showing a configuration example of a second video signal receiving device according to a second embodiment. FIG. 9 is a block diagram showing a configuration example of a third video signal receiving device according to a second embodiment. 9 is a flowchart showing a processing example of the first video signal receiving apparatus according to the second embodiment. 9 is a flowchart showing a processing example of the second video signal receiving apparatus according to the second embodiment. 9 is a flowchart showing a processing example of the third video signal receiving apparatus according to the second embodiment. It is a figure explaining 5-3 conversion in Example 2. It is a figure explaining classification of a frame. It is a figure explaining 10-bit-ized data and 12-bit-ized data. 3 is a schematic diagram showing an example of the overall configuration of a video signal transmitting / receiving system according to Example 2. FIG. FIG. 10 is a block diagram showing a configuration example of a video signal transmission device according to a third embodiment. FIG. 11 is a block diagram showing a configuration example of a first video signal receiving device according to a third embodiment. FIG. 10 is a block diagram showing a configuration example of a second video signal receiving device according to a third embodiment. FIG. 11 is a block diagram showing a configuration example of a third video signal receiving device according to a third embodiment. 11 is a flowchart showing a processing example of the first video signal receiving apparatus according to the third embodiment. 11 is a flowchart showing a processing example of the second video signal receiving apparatus according to the third embodiment. 11 is a flowchart showing a processing example of the third video signal receiving apparatus according to the third embodiment. FIG. 9 is a schematic diagram showing an example of the overall configuration of a video signal transmitting / receiving system according to a third embodiment. FIG. 19 is a diagram illustrating a process of layering by performing 5-3 conversion in the time axis direction in the fourth embodiment. FIG. 14 is a block diagram showing a configuration example of a video signal transmission device according to a fourth embodiment. 9 is a flowchart showing a processing example of a video signal transmitting device according to a fourth embodiment. FIG. 16 is a block diagram showing a configuration example of a video signal receiving device according to a fourth embodiment. 13 is a flowchart showing a processing example of the video signal receiving device according to the fourth embodiment. It is the schematic which shows the whole structural example of the conventional video signal transmission / reception system.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

[Down-convert / Wavelet 5-3 Two-dimensional reversible conversion method]
First, the down-conversion processing used in the following first to fourth embodiments will be described. This down-conversion processing is processing performed by the wavelet 5-3 two-dimensional reversible conversion method for down-converting the video signal while maintaining the reversibility, and the compression encoding for removing the high frequency component from the original signal. Not processing.

  FIG. 1 is a conceptual diagram illustrating the wavelet 5-3 two-dimensional lossless conversion method. FIG. 1A shows a process of 5-3 conversion by a horizontal wavelet 5-3 two-dimensional reversible conversion method, and corresponds to Expression (1) described later. FIG. 1B shows a process of 5-3 conversion in the vertical direction, and corresponds to Expression (1) described later. FIG. 1C shows a process of 5-3 conversion in the horizontal direction, and corresponds to Expression (2) described later. FIG. 1D shows a process of 5-3 conversion in the vertical direction, and corresponds to Expression (2) described later.

  Generally, in the process of down-converting an image, aliasing distortion occurs by simply thinning out pixels. In order to prevent this, averaging processing is performed between pixels. A division is performed in the averaging process, and the lower bits are truncated in the division result so as to fit in the video frame for transmission, so that a rounding error occurs.

  On the other hand, in the processing of down conversion by the wavelet 5-3 two-dimensional reversible conversion method, bit truncation by division is performed. However, during the inverse conversion for up-converting the signal after the down-conversion, the original signal can be restored without causing a rounding error due to the relationship of the pixel portions to be processed.

The formulas for 5-3 conversion are shown in formulas (1) and (2), and the formulas for 5-3 reverse conversion, which is the inverse thereof, are shown in formulas (3) and (4).

  In the formulas (1) to (4), X represents a pixel value of the original image, and Y represents a pixel value after conversion calculated from the original image by 5-3 conversion.

  The processing of the equation (1) operates as a high-pass filter that represents the difference between neighboring three-point pixels, and the processing of the equation (2) is a low-pass that is a weighted average value among the neighboring three-point pixels. Acts as a filter. That is, the formulas (1) and (2) are applied to a certain image in the horizontal direction and the vertical direction (hereinafter, referred to as the horizontal and vertical directions). Then, as shown in FIGS. 1A and 1B, the horizontal and vertical directions are decimated by half, and an image having a resolution of 1/2 in the horizontal and vertical directions with respect to the original image is generated. The generated 1/2 resolution image has the same result as that of the good down-conversion processing.

  Similarly, the original two-dimensional image value (original image) can be restored by the equations (3) and (4) using the video signal generated by the processing of the equations (1) and (2).

  FIG. 2 is a schematic diagram illustrating images before and after conversion by the wavelet 5-3 two-dimensional reversible conversion method. The hH1 (horizontal High pass filter: horizontal high-pass filter) unit is generated from the original image according to the formula (1), and is a result of applying the high-pass filter in the horizontal direction to the original image. The number is halved. The hL1 (horizontal Low pass filter) part is a result of applying the low-pass filter in the horizontal direction to the original image and the hH1 part, which is generated from the original image and the hH1 part according to the formula (2). , The number of pixels in the horizontal direction is half that of the original image.

  The vH1 (vertical high pass filter) part is generated from the hL1 part according to the above equation (1), and is a result of applying the high pass filter in the vertical direction to the hL1 part, which is in the horizontal and vertical directions with respect to the original image. The number of pixels is halved. A vL1 (vertical low pass filter) unit is generated from the hL1 unit and the vH1 unit according to the equation (2), and is a result of applying a low-pass filter in the vertical and horizontal directions to the original image. The number of pixels in the horizontal and vertical directions is half that of the original image. That is, the vL1 part is a down-converted image in which the original image is smoothed.

  Similarly, the vL1 part is subjected to 5-3 conversion by the above equations (1) and (2) to generate the hH2 part, the vH2 part, and the vL2 part. The vL2 portion is a down-converted image having 1/4 the number of pixels in each of the horizontal and vertical directions with respect to the original image.

  On the other hand, according to the equations (3) and (4), the hL1 part can be reproduced from the vL1 part and the vH1 part by the 5-3 inverse transform, and the original image can be reproduced from the hL1 part and the hH1 part. it can. That is, the original image can be reproduced from the vL1 part, the vH1 part, and the hH1 part, and the total number of pixels of the vL1 part, the vH1 part, and the hH1 part is the same as the number of pixels of the original image.

  In this way, the vL2 part, which is an image that is ½ down-converted in the horizontal and vertical directions, is generated based on the vL1 part that is the down-converted image. Also, based on the vH1 part and the hH1 part in addition to the vL1 part, an original image which is an image obtained by 1/2 up-converting the vL1 part in the horizontal and vertical directions is reproduced. Similarly, the vL1 part is reproduced based on the vL2 part, the vH2 part, and the hH2 part.

[Example 1]
Next, Example 1 will be described. In the first embodiment, in the video signal transmitting device, a predetermined uncompressed hierarchical image is generated from the original image, the non-compressed hierarchical video signal is transmitted, and the video signal receiving device receives the hierarchical video signal. To play and output the desired video.

  FIG. 3 is a diagram for explaining a hierarchical image and is similar to the image shown in FIG. As shown in FIG. 3, the hierarchical images of the hH portion and the hL portion are generated from the original image, and the hierarchical images of the vH portion and the vL portion are generated from the hL portion. When the original image is the original image, the hH portion is the hH1 portion in FIG. 2, the vH portion is the vH1 portion in FIG. 2, the vL portion is the vL1 portion in FIG. 2, and the hL portion is the hL1 portion. When the original image is the vL1 part of FIG. 2, the hH part is the hH2 part of FIG. 2, the vH part is the vH2 part of FIG. 2, and the vL part is the vL2 part of FIG. Hereinafter, the hierarchical images of the hH part, the vH part, and the vL part are simply referred to as hH, vH, and vL.

(Sender / Example 1)
First, the transmitting side of the first embodiment will be described. FIG. 4 is a block diagram illustrating a configuration example of the video signal transmission device according to the first embodiment. The video signal transmission device 1-1 includes an original image acquisition unit 10, a 5-3 conversion unit 11, a framing header addition unit 12, and a packet transmission unit 13.

  The original image acquisition unit 10 acquires an original image by inputting a video signal. The 5-3 conversion unit 11 inputs the original image from the original image acquisition unit 10, performs 5-3 conversion in the horizontal direction based on the original image, and generates hH1 and hL1.

  The 5-3 conversion unit 11 performs 5-3 conversion in the vertical direction based on hL1 to generate vH1 and vL1. Then, the 5-3 conversion unit 11 outputs hH1, vH1, and vL1 to the framing header addition unit 12.

  The 5-3 conversion unit 11 performs 5-3 conversion in the horizontal and vertical directions based on the original image to generate hH1, vH1 and vL1 of the first layer, and hH1, vH1 of the first layer. And vL1 are output. On the other hand, the 5-3 conversion unit 11 may further perform 5-3 conversion in the horizontal and vertical directions based on vL1 to generate hH2, vH2, and vL2 of the second layer. In this case, the 5-3 conversion unit 11 outputs hH1 and vH1 of the first layer and hH2, vH2 and vL2 of the second layer to the framing header addition unit 12.

  That is, the 5-3 conversion unit 11 performs the 5-3 conversion in the horizontal and vertical directions according to the preset nth hierarchy or the nth hierarchy requested by another device, to the nth hierarchy. Generate hHn, vHn, and vLn of hierarchy. Then, the original image acquisition unit 10 outputs the first to n-th hierarchical images (hH1, vH1, hH2, vH2, hH3, vH3, ..., HHn, vHn, vLn). However, n is an integer of 2 or more.

  The framing header adding unit 12 inputs hH1, vH1 and vL1 from the 5-3 converting unit 11. Then, the framing header adding unit 12 adds a framing header including a flag for distinguishing hH1, vH1 and vL1 or a multicast address (discrimination information) to hH1, vH1 and vL1. The framing header adding unit 12 outputs hH1, vH1 and vL1 with the framing header added to the packet transmitting unit 13.

  The packet transmission unit 13 inputs hH1, vH1 and vL1 to which the framing header is added from the framing header addition unit 12 to generate packets of hH1, vH1 and vL1, respectively, and packets of hH1, vH1 and vL1 as hierarchical video signals. To send.

  In this way, the packets of hH1, vH1, and vL1 are transmitted from the video signal transmitting device 1-1 as the hierarchical video signal of the first hierarchy. When the layer video signals of the layers up to the nth layer are transmitted, packets of hH1, vH1, hH2, vH2, hH3, vH3, ..., HHn, vHn, vLn are transmitted. The layer of the hierarchical image generated by the 5-3 conversion unit 11 of the video signal transmitting apparatus 1-1 and the layer of the hierarchical video signal transmitted from the packet transmitting unit 13 are received by the video signal receiving apparatus 2-1 described later. It is set according to the hierarchical video signal.

  FIG. 5 is a flowchart showing a processing example of the video signal transmitting apparatus 1-1 shown in FIG. 4, and shows processing when transmitting one frame of video. When the original image acquisition unit 10 of the video signal transmission device 1-1 acquires the original image, the 5-3 conversion unit 11 determines whether the acquisition of 3 pixels in the horizontal direction has been completed for the video signal of the original image. The determination is made (step S501).

  If the 5-3 conversion unit 11 determines in step S501 that acquisition of the three pixels in the horizontal direction has not been completed (step S501: N), the 5-3 conversion unit 11 waits until the process is completed.

  When the 5-3 conversion unit 11 determines in step S501 that the acquisition of the three pixels in the horizontal direction has been completed (step S501: Y), the 5-3 conversion unit 11 performs the 5-3 conversion in the horizontal direction based on the original image, and hH1 And hL1 are generated (step S502). Then, the framing header addition unit 12 adds a framing header to hH1, and the packet transmission unit 13 generates and transmits a packet of hH1 (step S503).

  When the 5-3 conversion unit 11 processes the n-th layer, it generates hHn and hLn, the framing header adding unit 12 adds a framing header to hHn, and the packet transmission unit 13 uses the hHn. Generate and send a packet.

  The 5-3 conversion unit 11 proceeds from step S502 to determine whether or not the acquisition of the three pixels in the vertical direction has been completed for the hL1 video signal (step S504).

  When the 5-3 conversion unit 11 determines in step S504 that acquisition of the three pixels in the vertical direction has not been completed (step S504: N), the 5-3 conversion unit 11 waits until the process is completed.

  When the 5-3 conversion unit 11 determines in step S504 that the acquisition of the three pixels in the vertical direction has been completed (step S504: Y), the 5-3 conversion unit 11 performs 5-3 conversion in the vertical direction based on hL1, and vH1 and vL1 is generated (step S505). Then, the framing header adding unit 12 adds framing headers to vH1 and vL1, respectively, and the packet transmitting unit 13 generates and transmits packets of vH1 and vL1 (step S506).

  When the second layer is also processed, the framing header adding unit 12 adds the framing header to the first hH1 and vH1 and the packet transmitting unit 13 sets the first layer to the first layer. The packets of hH1 and vH1 are generated and transmitted. Further, for the second layer, the 5-3 conversion unit 11 generates hH2 and hL2 based on vL1, and vH2 and vL2 based on hL2. Then, the framing header addition unit 12 adds a framing header to the second hH2, vH2, and vL2, and the packet transmission unit 13 generates and transmits the second hH2, vH2, and vL2 packets.

  That is, when processing is also performed on the n-th layer, the 5-3 conversion unit 11 generates hHn-1 and hLn-1 based on vLn-2 for the (n-1) th layer, and hLn-1 VHn-1 and vLn-1 are generated based on Then, the framing header adding unit 12 adds a framing header to the (n-1) th hHn-1 and vHn-1, and the packet transmission unit 13 uses the n-1th hHn-1 and vHn-1 packet. Generate and send. Further, for the nth layer, the 5-3 conversion unit 11 generates hHn and hLn based on vLn−1, and generates vHn and vLn based on hLn. Then, the framing header adding unit 12 adds a framing header to the nth hHn, vHn, and vLn, and the packet transmission unit 13 generates and transmits the nth hHn, vHn, and vLn packet. Accordingly, when transmitting hierarchical images up to the n-th hierarchical layer, packets of hH1, vH1, hH2, vH2, hH3, vH3, ..., hHn, vHn, vLn are transmitted from the video signal transmitting apparatus 1-1. Sent.

  As described above, according to the video signal transmission device 1-1 of the first embodiment, the 5-3 conversion unit 11 performs 5-3 conversion in the horizontal direction based on the original image to generate hH1 and hL1. A vertical 5-3 conversion is performed based on hL1 to generate vH1 and vL1. Then, the framing header adding unit 12 adds, to hH1, vH1, and vL1, a framing header including a flag or a multicast address for distinguishing these hierarchical images. The packet transmission unit 13 transmits packets of hH1, vH1, and vL1 as hierarchical video signals.

  When processing up to the n-th layer, hH1, vH1, hH2, vH2, hH3, vH3, ..., hHn, vHn, vLn are obtained by 5-3 conversion in the horizontal and vertical directions in the 5-3 conversion unit 11. Generated, these packets are transmitted as a hierarchical video signal.

  Thereby, the video signal receiving device 2-1 described later can reproduce the video of the desired resolution by receiving only the hierarchy video signal of the desired hierarchy. That is, it is not necessary to separately reproduce images of different resolutions from one video signal in which the precision of the highest resolution is maintained.

  Therefore, only the hierarchy video signal of the hierarchy corresponding to the video signal receiving device 2-1 is transmitted, and the accuracy of the video signal does not decrease. Further, since the 5-3 conversion is not a compression encoding process for removing high frequency components from the original signal, it is possible to realize low-delay transmission as compared with the case of performing the compression encoding process.

(Receiving side / Example 1)
Next, the receiving side of the first embodiment will be described. FIG. 6 is a block diagram illustrating a configuration example of the video signal receiving device according to the first embodiment. The video signal receiving device 2-1 includes a packet receiving unit 20, a data extracting unit 21, and a 5-3 inverse converting unit 22.

  The packet receiving unit 20 receives the packets of hH1, vH1, and vL1 which are the hierarchical video signals transmitted from the video signal transmitting device 1-1, and distinguishes the hierarchical images based on the framing header included in the packets. Then, the packet receiving unit 20 acquires hH1, vH1, and vL1 by extracting hH1, vH1, and vL1 from each packet. The packet receiving unit 20 outputs hH1, vH1 and vL1 to the data extracting unit 21.

  The data extraction unit 21 inputs hH1, vH1 and vL1 from the packet reception unit 20, extracts vL1 from hH1, vH1 and vL1 and outputs this as a low resolution video signal vL1. As a result, the low-resolution video signal vL1 is used to perform low-resolution video display processing and the like in the first layer.

  When the packet receiving unit 20 receives the packets of hH1, vH1, hH2, vH2, hH3, vH3, ..., HHn, vHn, vLn of the layers up to the nth layer, the data extracting unit 21 determines that VLn is extracted from the packet and is output as a low resolution video signal vLn. As a result, low-resolution video signal vLn is used to perform low-resolution video display processing and the like in the n-th layer.

  The data extraction unit 21 outputs hH1, vH1, and vL1 to the 5-3 inverse conversion unit 22 so that the 5-3 inverse conversion unit 22 in the subsequent stage reproduces a high-resolution image.

  The 5-3 inverse transformation unit 22 inputs hH1, vH1 and vL1 from the data extraction unit 21, performs 5-3 inverse transformation in the vertical direction based on vH1 and vL1, and reproduces hL1. Then, the 5-3 inverse conversion unit 22 performs 5-3 inverse conversion in the horizontal direction based on the input hH1 and the reproduced hL1, and reproduces the original image. The 5-3 inverse conversion unit 22 outputs the reproduced original image as a high-resolution video signal. As a result, the display processing of the original image and the like are performed using the original image that is a high-resolution video signal.

  When the packet receiving unit 20 receives the packets of hH1, vH1, hH2, vH2, hH3, vH3, ..., HHn, vHn, vLn of the layers up to the nth layer, the data extracting unit 21 determines that Outputs hH1, vH1, hH2, vH2, hH3, vH3, ..., HHn, vHn, vLn to the 5-3 inverse conversion unit 22.

  The 5-3 inverse conversion unit 22 inputs hH1, vH1, hH2, vH2, hH3, vH3, ..., HHn, vHn, vLn from the data extraction unit 21. Then, the 5-3 inverse transformation unit 22 performs 5-3 inverse transformation in the vertical and horizontal directions based on the hHn, vHn, and vLn of the nth layer to reproduce vLn-1 of the n-1th layer. The 5-3 inverse conversion unit 22 sequentially performs the 5-3 inverse conversion in the vertical and horizontal directions toward the upper layer, and reproduces vL1 of the first layer. Then, the 5-3 inverse conversion unit 22 performs 5-3 inverse conversion in the vertical and horizontal directions based on hH1, vH1, and vL1, reproduces the original image, and outputs the reproduced original image as a high-resolution video signal. ..

  In this case, the 5-3 inverse conversion unit 22 may output the vL1 video signal of the first layer instead of the original image, or may output the vL2 video signal of the second layer. You may do so. For example, when the original image is an 8K video, the 5-3 inverse conversion unit 22 can output an 8K video signal, a 4K video signal, and a 2K video signal. It is also possible to output one or two video signals.

  FIG. 7 is a flowchart showing a processing example of the video signal receiving device 2-1 shown in FIG. 6, and shows processing when receiving one frame of video frame. The packet receiving unit 20 of the video signal receiving device 2-1 receives the packets of hH1, vH1, and vL1 which are hierarchical video signals, and acquires hH1, vH1 and vL1 (step S701).

  The data extraction unit 21 determines a preset video processing type (step S702), and when performing low resolution processing, extracts vL1 and outputs it as a low resolution video signal vL1 (step S703). ..

  In step S702, the data extraction unit 21 outputs hH1, vH1, and vL1 to the 5-3 inverse conversion unit 22 when performing high-resolution processing. The 5-3 inverse conversion unit 22 determines whether or not acquisition of 3 pixels in the vertical direction has been completed for vH1 and vL1 (step S704).

  When the 5-3 inverse conversion unit 22 determines in step S704 that acquisition of the three pixels in the vertical direction has not been completed (step S704: N), the 5-3 inverse conversion unit 22 waits until the process is completed.

  When the 5-3 inverse transform unit 22 determines in step S704 that the acquisition of the three pixels in the vertical direction has been completed (step S704: Y), the 5-3 inverse transform unit 22 performs the 5-3 inverse transform in the vertical direction based on vH1 and vL1. Then, hL1 is reproduced (step S705).

  In step S705, the 5-3 inverse conversion unit 22 reproduces hL2 when processing the second hierarchical layer, and reproduces hLn when processing the nth hierarchical layer.

  The 5-3 inverse conversion unit 22 shifts from step S705, and determines whether or not acquisition of 3 pixels in the horizontal direction has been completed for hH1 and hL1 (step S706). When the 5-3 inverse conversion unit 22 determines in step S706 that the acquisition of the three pixels in the horizontal direction has not been completed (step S706: N), the 5-3 inverse conversion unit 22 waits until the processing is completed.

  When the 5-3 inverse conversion unit 22 determines in step S706 that the acquisition of the three pixels in the horizontal direction has been completed (step S706: Y), the 5-3 inverse conversion unit 22 performs the 5-3 inverse conversion in the horizontal direction based on hH1 and hL1. Then, the original image is reproduced (step S707). Then, the 5-3 inverse conversion unit 22 outputs this as a high-resolution video signal (step S708).

  In addition, in step S707, the 5-3 inverse conversion unit 22 reproduces hL1 as described above when processing the second hierarchical layer, and reproduces hLn-1 when processing the nth hierarchical layer. ..

  As described above, according to the video signal reception device 2-1 of the first embodiment, the packets of hH1, vH1, and vL1 are received as the hierarchical video signal, and the data extraction unit 21 extracts vL1 and sets it to the low resolution. Is output as the video signal vL1. The 5-3 inverse transform unit 22 performs a 5-3 inverse transform in the vertical direction based on vH1 and vL1, reproduces hL1, and performs a 5-3 inverse transform in the horizontal direction based on hH1 and hL1. The original image is reproduced and this is output as a high resolution video signal.

  It is assumed that the video signal receiving device 2-1 receives packets of hH1, vH1, hH2, vH2, hH3, vH3, ..., HHn, vHn, vLn as hierarchical video signals of the layers up to the nth layer. To do. The data extraction unit 21 extracts vLn and outputs it as a low-resolution video signal vLn. In addition, the 5-3 inverse conversion unit 22 sequentially performs 5-3 inverse conversion in the vertical and horizontal directions from the n-th layer to the upper layer to reproduce vL1 of the first layer, and then the original image. To play. The 5-3 inverse conversion unit 22 outputs the reproduced hierarchical image as a video signal having a desired resolution.

  As a result, the video signal receiving device 2-1 can reproduce the video of the desired resolution by receiving only the hierarchy video signal of the desired hierarchy. That is, it is not necessary to separately reproduce images of different resolutions from one video signal in which the precision of the highest resolution is maintained.

  Therefore, only the hierarchy video signal of the hierarchy corresponding to the video signal receiving device 2-1 is transmitted, and the accuracy of the video signal does not decrease. Further, since the 5-3 conversion is not a compression encoding process for removing high frequency components from the original signal, it is possible to realize low-delay transmission as compared with the case of performing the compression encoding process.

  The video signal receiving device 2-1 of the first embodiment shown in FIG. 6 includes a data extraction unit 21 for reproducing a low resolution image and a 5-3 inverse conversion unit for reproducing a high resolution image. However, it may have a function of reproducing only low-resolution video. In this case, the video signal receiving device 2-1 includes only the data extraction unit 21 and does not include the 5-3 inverse conversion unit 22. Further, the video signal receiving device 2-1 may have a function of reproducing only high-resolution video.

(System / Example 1)
Next, the video signal transmission / reception system of the first embodiment will be described. FIG. 8 is a schematic diagram showing an example of the overall configuration of the video signal transmitting / receiving system according to the first embodiment. This video signal transmission / reception system includes a video signal transmission device 1-1, video signal reception devices 2-1a, 2-1b, 2-1c and a router 3-1.

  The video signal transmission device 1-1 includes the configuration unit shown in FIG. 4, and in this example, by performing the processing shown in FIGS. 4 and 5, hH1, vH1, Generate hH2, vH2, vL2. Then, the video signal transmission device 1-1 transmits packets of hH1, vH1, hH2, vH2, and vL2 as hierarchical video signals to the router 3-1.

  The router 3-1 constitutes a matrix switch for transferring a packet. The same applies to the router 3-2 and the like described later. The router 3-1 receives packets of hH1, vH1, hH2, vH2, and vL2 as hierarchical video signals from the video signal transmission device 1-1 and transmits them from the video signal reception devices 2-1a, 2-1b, 2-1c. Receive the request. Then, the router 3-1 selects the packet of the hierarchical image corresponding to the transmission request based on the flag of the framing header included in the packet or the multicast address. The router 3-1 transmits the selected packet as a hierarchical video signal to the video signal receiving devices 2-1a, 2-1b, 2-1c that have transmitted the transmission request.

  In the case of this example, when the router 3-1 receives the transmission request for the high-resolution hierarchical image from the video signal receiving device 2-1a, it responds to the transmission request from the packets of hH1, vH1, hH2, vH2, and vL2. Select packets of hH1, vH1, hH2, vH2, vL2. Then, the router 3-1 transmits the packets of hH1, vH1, hH2, vH2, and vL2 as high-resolution hierarchical video signals to the video signal receiving device 2-1a.

  When the router 3-1 receives the transmission request for the medium-resolution hierarchical image from the video signal receiving device 2-1b, the router 3-1 selects hH2, vH2, vL2 corresponding to the transmission request from the packets of hH1, vH1, hH2, vH2, vL2. Select the packet. Then, the router 3-1 transmits packets of hH2, vH2, and vL2 as a medium-resolution hierarchical video signal to the video signal receiving device 2-1b.

  When the router 3-1 receives the transmission request for the low-resolution hierarchical image from the video signal receiving device 2-1c, it selects the vL2 packet corresponding to the transmission request from the hH1, vH1, hH2, vH2, and vL2 packets. To do. Then, the router 3-1 transmits the vL2 packet as a low-resolution hierarchical video signal to the video signal receiving device 2-1c.

  The video signal receiving devices 2-1a, 2-1b, 2-1c are provided with the components shown in FIG. 6, and transmit a transmission request for acquiring a desired hierarchical image to the router 3-1. The hierarchical video signal of the hierarchical layer corresponding to the transmission request is received. Then, the video signal receiving devices 2-1a, 2-1b, 2-1c reproduce the desired video by performing the processing shown in FIGS. 6 and 7 according to the received hierarchical video signal of the hierarchy. .

  The video signal receiving device 2-1a is, for example, a high-resolution monitor, and in order to acquire a high-resolution hierarchical image, a transmission request including data (for example, a flag or a multicast address) for distinguishing the high-resolution hierarchical image. Is generated and the transmission request is transmitted to the router 3-1. Then, the video signal receiving device 2-1a receives the packets of hH1, vH1, hH2, vH2, and vL2 from the router 3-1 as high-resolution hierarchical video signals.

  The video signal receiving device 2-1a outputs vL2 as a low-resolution video signal, performs vertical-horizontal 5-3 inverse conversion based on hH2, vH2, and vL2, reproduces vL1, and reproduces vL1. Output as a video signal. Further, the video signal receiving device 2-1a performs the vertical-horizontal direction 5-3 inverse conversion based on hH1, vH1, and vL1, reproduces the original image, and outputs this as the image signal of the original image.

  The video signal receiving device 2-1b is, for example, a medium-resolution monitor, generates a transmission request including data for distinguishing the medium-resolution hierarchical image, and acquires the transmission request in order to obtain the medium-resolution hierarchical image. To the router 3-1. Then, the video signal receiving device 2-1b receives packets of hH2, vH2, and vL2 from the router 3-1 as a hierarchical video signal of medium resolution.

  The video signal receiving device 2-1b outputs vL2 as a low-resolution video signal, performs vertical-horizontal 5-3 inverse conversion based on hH2, vH2, and vL2, reproduces vL1, and reproduces vL1. Output as a video signal.

  The video signal receiving device 2-1c is, for example, a low-resolution monitor, generates a transmission request including data for distinguishing the low-resolution hierarchical image and acquires the transmission request in order to obtain the low-resolution hierarchical image. To the router 3-1. Then, the video signal receiving device 2-1c receives the vL2 packet as a low-resolution hierarchical video signal from the router 3-1. The video signal receiving device 2-1c outputs vL2 as a low-resolution video signal.

  As described above, according to the video signal transmission / reception system of the first embodiment, the video signal transmission device 1-1 generates hH1, vH1, hH2, vH2, and vL2 that are the hierarchical images of the layers up to the second layer, These packets are transmitted to the router 3-1 as hierarchical video signals. The router 3-1 uses the packet of the hierarchical image corresponding to the transmission request from the video signal receiving devices 2-1a, 2-1b, and 2-1c as the hierarchical video signal and transmits the transmission request. It transmits to 2-1a, 2-1b, 2-1c.

  The video signal receiving device 2-1a receives the hierarchical video signals of hH1, vH1, hH2, vH2, and vL2, which are high-resolution hierarchical images corresponding to the transmission request, and reproduces vL1 and the original image by 5-3 reverse conversion. To do. Further, the video signal receiving device 2-1b receives the hierarchical video signals of hH2, vH2, and vL2, which are medium-resolution hierarchical images corresponding to the transmission request, and reproduces vL1 by 5-3 inverse conversion. Further, the video signal receiving device 2-1c receives the vL2 hierarchical video signal, which is a low-resolution hierarchical image corresponding to the transmission request.

  As a result, as described above, the same effects as the video signal transmission device 1-1 according to the first embodiment and the same effects as the video signal reception device 2-1 are obtained. Further, the video signal receiving devices 2-1a, 2-1b, 2-1c need only receive the desired hierarchical video signal from the router 3-1 and the router 3-1 also only receives the corresponding hierarchical video signal. May be received from the video signal transmitting device 1-1. Furthermore, the down conversion function by the conventional down converters 103-1 and 103-2 shown in FIG. 39 can be included in the video signal transmission device 1-1. Therefore, unlike the conventional router 104 shown in FIG. 39, the router 3-1 does not need to input video signals of a plurality of different resolutions, so that the number of input ports and the input signal band in the router 3-1 are reduced. be able to.

  The video signal transmission / reception system according to the first embodiment shown in FIG. 8 includes a high-resolution video signal reception device 2-1a, a medium-resolution video signal reception device 2-1b, and a low-resolution device as a reception side device. And a video signal receiving device 2-1c for use with. On the other hand, the video signal transmission / reception system may include one or more of the three video signal reception devices 2-1a, 2-1b, and 2-1c as the reception side device. The video signal transmitting / receiving system may further include a video signal receiving device for another resolution. In this case, the video signal transmission device 1-1 generates and transmits a hierarchical video signal corresponding to the resolution desired by the receiving side.

[Example 2]
Next, a second embodiment will be described. The second embodiment is an example of transmitting the uncompressed hierarchical video signals of 8K video, 4K video, and 2K video that match the Ethernet band in the first embodiment.

  Ethernet transmission systems have various line speeds defined by standardized specifications. Ethernet of 1 Gbps, 10 Gbps, 40 Gbps, 100 Gbps (future 400 Gbps, 1 Tbps) is currently defined as a method capable of high-speed transmission of gigabit or higher. The line speed of the Ethernet is represented by the transmission speed of the entire packet including the header portion and the footer portion other than the net data transmitted in the payload portion. Therefore, the net data transmission rate is about 98% of the transmission rate of the entire packet when the interframe gap (InterFrameGap) is set to a minimum of 8 bits.

  On the other hand, in the case of the so-called 8K video signal format of ultra-high definition video, a resolution of 7680 × 4320, a maximum frame frequency of 120 Hz, and a maximum color depth of 12 bits are specified. When the frame frequency is 120 Hz and the color depth of each color of RGB is 12 bits, the transmission speed is about 144 Gbps. Here, when the RGB values are converted into YUV values in the YUV 4: 2: 2 format, the transmission speed becomes 98 Gbps, and the video signal can be transmitted by one 100 Gbps Ethernet.

  In the case of 4K video, a resolution of 3840 × 2160, a maximum frame frequency of 60 Hz, and a maximum color depth of 10 bits are defined. When the RGB values are converted into YUV values in the YUV 4: 2: 2 format, the maximum transmission rate becomes about 9.95 Gbps. Considering the net data transmission rate, the video signal cannot be transmitted by one 10 Gbps Ethernet. Here, when the RGB values are converted into YUV values in the YUV 4: 2: 0 format, the maximum transmission speed becomes about 7.46 Gbps, and the video signal can be transmitted by one 10 Gbps Ethernet.

  For 2K video, a resolution of 1920 × 1080, a maximum frame frequency of 60 Hz, and a maximum color depth of 10 bits are defined. When the RGB values are converted into YUV values in the YUV 4: 2: 2 format, the maximum transmission speed becomes about 1.2 Gbps, and the video signal cannot be transmitted by one 1 Gbps Ethernet. Here, when the RGB values are converted into YUV values in the YUV 4: 2: 0 format, the maximum transmission speed becomes about 933 Mbps, and the video signal can be transmitted by one 1 Gbps Ethernet. When using 2K video for monitoring, a color depth of 8 bits is sufficient. Therefore, when transmitting in YUV 4: 2: 0 format with a color depth of 8 bits, the maximum transmission speed is about 746 Mbps.

  In the second embodiment, the video signal transmitting apparatus transmits a video signal of 8K video, a video signal of 4K video, and a hierarchical video signal capable of reproducing 2K video by one 100G Ethernet. Further, the video signal receiving device receives a desired hierarchical video signal by one 100G Ethernet when reproducing 8K video. The video signal receiving apparatus receives a desired hierarchical video signal on one 10G Ethernet when reproducing 4K video, and receives a desired hierarchical video signal on one 1G Ethernet when reproducing 2K video.

(Sender / Example 2)
First, the transmitting side of the second embodiment will be described. FIG. 9 is a block diagram showing a configuration example of the video signal transmitting apparatus according to the second embodiment, and FIG. 13 is a flowchart showing a processing example of the video signal transmitting apparatus according to the second embodiment. The video signal transmission device 1-2 includes an original image acquisition unit 10, an RGB / YUV conversion unit 14, a 5-3 conversion unit 15, a frame classification unit 16, a 120 Hz frame processing unit 17, 60, a 120 Hz frame processing units 18 and 30. , 60, 120 Hz frame processing unit 19.

  The original image acquisition unit 10 acquires an original image by inputting a video signal. The RGB / YUV conversion unit 14 inputs the original image from the original image acquisition unit 10, converts the RGB values of the original image into YUV values using a predetermined conversion formula, and generates a signal in the YUV 4: 4: 4 format. (Step S1301). As a result, the RGB values of 8K, 120 Hz, and 12 bits (RGB values of 8K video in 12-bit units (consisting of 12 bits per pixel) operating at a frequency of 120 Hz) are converted into YUV values. Then, the RGB / YUV conversion unit 14 outputs the 8K-YUV converted into the YUV value to the 5-3 conversion unit 15.

  FIG. 22 is a diagram for explaining the 5-3 conversion in the second embodiment. In the RGB / YUV conversion unit 14, 8K-Y, 8K-U, 8K-V (8K-YUV) shown at the top of FIG. 22 are obtained. The resolution of 8K-YUV is 7680 × 4320. Also, 8K-YUV is a signal of YUV 4: 4: 4 format, and its bit rate is 144 Gbps.

  Returning to FIG. 9, the 5-3 conversion unit 15 inputs 8K-YUV from the RGB / YUV conversion unit 14, performs 5-3 conversion in the horizontal direction based on 8K-UV, and 8K-U (hL1). And 8K-V (hL1) are generated (step S1302). Hereinafter, U (*) and V (*) are described as UV (*). Then, the 5-3 conversion unit 15 outputs 8K-Y and 8K-UV (hL1) to the frame classification unit 16.

  As a result, in the 5-3 conversion unit 15, 8K-UV (hL1), which is a hierarchical image of 8K-U (hL1) and 8K-V (hL1) shown in the second row from the top of FIG. 22, is obtained. The resolution of 8K-UV (hL1) is 3840 × 4320, respectively. 8K-Y and 8K-UV (hL1) are signals in YUV 4: 2: 2 format.

  The frame classification unit 16 inputs 8K-Y and 8K-UV (hL1) from the 5-3 conversion unit 15, and classifies each frame of 8K-Y and 8K-UV (hL1) into three types of frames ( Step S1303). The three types of frames are a 120 Hz frame for 120 Hz, a 60 and 120 Hz frame commonly used for 60 Hz and 120 Hz, and a 30, 60 and 120 Hz frame commonly used for 30 Hz, 60 Hz and 120 Hz. Then, the frame classification unit 16 outputs the 120 Hz frame to the 120 Hz frame processing unit 17, and outputs the 60 and 120 Hz frames to the 60 and 120 Hz frame processing unit 18. The frame classification unit 16 also outputs 30, 60, 120 Hz frames to the 30, 60, 120 Hz frame processing unit 19.

  FIG. 23 is a diagram illustrating classification of frames. As shown in FIG. 23, the Y and UV (hL1) frames are configured in the time axis direction in units of four frames in the order of 120 Hz frame, 60, 120 Hz frame, 120 Hz frame, and 30, 60, 120 Hz frame. .. The frame classifying unit 16 classifies three types of frames of 120 Hz frame, 60, 120 Hz frame, and 30, 60, 120 Hz frame from a series of frames in the time axis direction in units of 4 frames.

  Returning to FIG. 9, the 120 Hz frame processing unit 17 inputs a 120 Hz frame (8K-Y and 8K-UV (hL1) frame) from the frame classification unit 16 and performs 120 Hz frame processing (step S1304). Details of the 120 Hz frame processing will be described later. Then, the 120 Hz frame processing unit 17 assigns a multicast address or the like and classifies the packets, and then transmits 8K-Y and 8K-UV (hL1) packets as hierarchical video signals.

  The 60,120 Hz frame processing unit 18 inputs the 60,120 Hz frame (8K-Y and 8K-UV (hL1) frame) from the frame classification unit 16 and performs 60,120 Hz frame processing (step S1305). Then, the 60, 120 Hz frame processing unit 18 generates 4K-Y (hH1, vH1, vL1) and 4K-UV (hH2, vH2, vL2) as shown in the third row from the top of FIG. 12-bit data is separated from the original signal. 4K-Y (hH1, vH1, vL1) and 4K-UV (hH2, vH2, vL2) are composed of 10-bit video signals. The resolution of 4K-Y (vL1) is 3840 x 2160, and the resolution of 4K-UV (vL2) is 1920 x 1080, respectively. Details of the 60 and 120 Hz frame processing will be described later.

  FIG. 24 is a diagram illustrating 10-bit data and 12-bit data. The video signals (original signals) of the 120 Hz frame, 60, 120 Hz frame, and 30, 60, 120 Hz frame output by the frame classifying unit 16 are all 12 bits long. When upper 10-bit data and lower 2-bit data are separated from the 12-bit data, the lower 2-bit data is referred to as 12-bit data. Further, when upper 8-bit data and lower 2-bit data are separated from 10-bit data, the lower 2-bit data is referred to as 10-bit data. The 10-bit data is generated by the 30, 60, 120 Hz frame processing unit 19 described later.

  Returning to FIG. 9, the 60 and 120 Hz frame processing unit 18 classifies each hierarchical image and 12-bit data by adding a multicast address or the like. Then, the 60, 120 Hz frame processing unit 18 transmits packets of 4K-Y (hH1, vH1, vL1), 4K-UV (hH2, vH2, vL2) and 12-bit data as hierarchical video signals.

  The 30, 60, 120 Hz frame processing unit 19 inputs 30, 60, 120 Hz frames (8K-Y and 8K-UV (hL1) frames) from the frame classification unit 16 and performs 30, 60, 120 Hz frame processing ( Step S1306). Then, the 30, 60, 120 Hz frame processing unit 19 generates 2K-Y (hH2, vH2, vL2), 2K-UV (hH3, vH3, vL3) as shown in the lowermost part of FIG. The 30, 60, 120 Hz frame processing unit 19 separates the 10-bit data and the 12-bit data shown in FIG. 24 from the original signal. 2K-Y (hH2, vH2, vL2) and 2K-UV (hH3, vH3, vL3) are composed of 8-bit video signals. The resolution of 2K-Y (vL2) is 1920 x 1080, and the resolution of 2K-UV (vL3) is 960 x 540, respectively. Details of 30, 60, and 120 Hz frame processing will be described later.

  The 30, 60, 120 Hz frame processing unit 19 classifies each layer image, 12-bit data and 10-bit data by adding a multicast address or the like. Then, the 30, 60, 120 Hz frame processing unit 19 outputs 2K-Y (hH2, vH2, vL2), 2K-UV (hH3, vH3, vL3), 4K-Y (hH1, vH1), 4K- as hierarchical video signals. A packet of UV (hH2, vH2), 12-bit data and 10-bit data is transmitted.

(120 Hz frame processing unit 17)
Next, the 120 Hz frame processing unit 17 shown in FIG. 9 will be described. FIG. 10 is a block diagram showing a configuration example of the 120 Hz frame processing unit 17. The 120 Hz frame processing unit 17 includes a framing header addition unit 30a and a packet transmission unit 31a.

  The framing header adding unit 30a inputs 120 Hz frames (8K-Y and 8K-UV (hL1) frames) from the frame classifying unit 16 and adds framing headers such as multicast addresses to these. Then, the framing header adding unit 30a outputs 8K-Y and 8K-UV (hL1) to which the framing header is added to the packet transmitting unit 31a.

  The packet transmission unit 31a inputs 8K-Y and 8K-UV (hL1) to which the framing header is added from the framing header addition unit 30a, generates these packets, respectively, and outputs 8K-Y and 8K- as hierarchical video signals. The UV (hL1) packet is transmitted.

(60, 120Hz frame processing unit 18)
Next, the 60 and 120 Hz frame processing unit 18 shown in FIG. 9 will be described. 11 is a block diagram showing a configuration example of the 60,120 Hz frame processing unit 18, and FIG. 14 is a flowchart showing a processing example of the 60,120 Hz frame processing unit 18 (processing example of step S1305 in FIG. 13). .. The 60, 120 Hz frame processing unit 18 includes a data separating unit 32, a YUV classifying unit 33, a 5-3 converting unit 34, 35a, a framing header adding unit 30b, and a packet transmitting unit 31b.

  The data separation unit 32 inputs the 60, 120 Hz frame (8K-Y and 8K-UV (hL1) frame) from the frame classification unit 16. Then, the data separation unit 32 separates the upper 10-bit data and the lower 2-bit data from the 12-bit data of the 60 and 120 Hz frames (step S1401).

  The data separation unit 32 outputs 8K-Y and 8K-UV (hL1) consisting of upper 10-bit data to the YUV classification unit 33, and outputs lower 2-bit data to the framing header addition unit 30b as 12-bit data. To do.

  The framing header adding unit 30b inputs the 12-bit data from the data separating unit 32 and adds a framing header such as a multicast address. Then, the packet transmission unit 31b generates a packet of 12-bit data with the framing header added, and transmits the packet (step S1402).

  The YUV classification unit 33 inputs 8K-Y and 8K-UV (hL1) from the data separation unit 32, classifies YUV, outputs 8K-Y to the 5-3 conversion unit 34, and outputs 8K-UV (hL1). Is output to the 5-3 conversion unit 35a (step S1403).

  The 5-3 conversion unit 34 inputs 8K-Y from the YUV classification unit 33, performs 5-3 conversion in the horizontal and vertical directions based on 8K-Y, and as shown in the third row from the top of FIG. 4K-Y (hH1, vH1, vL1) is generated (step S1404). Then, the 5-3 conversion unit 34 outputs 4K-Y (hH1, vH1, vL1) to the framing header addition unit 30b.

  The framing header adding unit 30b inputs 4K-Y (hH1, vH1, vL1) from the 5-3 converting unit 34 and adds a framing header such as a multicast address. Then, the packet transmission unit 31b generates a 4K-Y (hH1, vH1, vL1) packet to which the framing header is added, and transmits the packet (step S1405, step S1406).

  The 5-3 conversion unit 35a receives 8K-UV (hL1) from the YUV classification unit 33. Then, the 5-3 conversion unit 35a performs 5-3 conversion in the vertical direction based on 8K-UV (hL1), and generates UV (vH1, vL1) as shown in the third row from the top of FIG. (Step S1407). As a result, a YUV 4: 2: 0 format signal is obtained.

  The 5-3 conversion unit 35a performs 5-3 conversion in the horizontal and vertical directions based on UV (vL1) to generate 4K-UV (hH2, vH2, vL2), and 4K-UV (hH2, vH2, vL2). Is output to the framing header adding unit 30b (step S1408).

  The framing header adding unit 30b inputs 4K-UV (hH2, vH2, vL2) from the 5-3 converting unit 35a and adds a framing header such as a multicast address. Then, the packet transmission unit 31b generates a 4K-UV (hH2, vH2, vL2) packet to which the framing header is added, and transmits the packet (steps S1409 and S1410).

  In this way, from the packet transmission unit 31b of the 60, 120 Hz frame processing unit 18, 4K-Y (hH1, vH1, vL1), 4K-UV (hH2, vH2, vL2) and 12-bit data are generated as hierarchical video signals. The packet is sent.

(30, 60, 120Hz frame processing unit 19)
Next, the 30, 60, 120 Hz frame processing unit 19 shown in FIG. 9 will be described. 12 is a block diagram showing a configuration example of the 30, 60, 120 Hz frame processing unit 19, and FIG. 15 shows a processing example of the 30, 60, 120 Hz frame processing unit 19 (processing example of step S1306 in FIG. 13). It is a flowchart shown. The 30, 60, 120 Hz frame processing unit 19 includes a data separating unit 36, a YUV classifying unit 37, a 5-3 converting unit 38, 35b, a framing header adding unit 30c, and a packet transmitting unit 31c.

  The data separation unit 36 inputs 30, 60, and 120 Hz frames (8K-Y and 8K-UV (hL1) frames) from the frame classification unit 16. Then, the data separation unit 36 separates the upper 10-bit data and the lower 2-bit data from the 12-bit data of the 30, 60, and 120 Hz frames (step S1501).

  The data separation unit 36 outputs the lower 2-bit data separated from the 12-bit data as 12-bit data to the framing header addition unit 30c.

  The framing header adding unit 30c inputs the 12-bit data from the data separating unit 36 and adds a framing header such as a multicast address. Then, the packet transmission unit 31c generates a packet of 12-bit data with the framing header added, and transmits the packet (step S1502).

  The data separating unit 36 separates the upper 8-bit data and the lower 2-bit data from the separated upper 10-bit data (step S1503).

  The data separation unit 36 outputs 8K-Y and 8K-UV (hL1) consisting of upper 8-bit data to the YUV classification unit 37. Further, the data separating unit 36 outputs the lower 2 bits of data separated from the upper 10 bits of data to the framing header adding unit 30c as 10-bit data.

  The framing header adding unit 30c inputs the 10-bit data from the data separating unit 36 and adds a framing header such as a multicast address. Then, the packet transmitting unit 31c generates a packet of 10-bit data with the framing header added, and transmits the packet (step S1504).

  The YUV classification unit 37 inputs 8K-Y and 8K-UV (hL1) from the data separation unit 36, classifies YUV, outputs 8K-Y to the 5-3 conversion unit 38, and outputs 8K-UV (hL1). Is output to the 5-3 conversion unit 35b (step S1505).

  The 5-3 conversion unit 38 inputs 8K-Y from the YUV classification unit 37, performs the same processing as step S1404 in FIG. 14, and generates 4K-Y (hH1, vH1, vL1) (step S1506). Then, the framing header addition unit 30c and the packet transmission unit 31c perform the same processing as step S1405 of FIG. 14 (step S1507). As a result, a 4K-Y (hH1, vH1) packet is transmitted.

  The 5-3 conversion unit 38 performs 5-3 conversion in the horizontal and vertical directions based on the 4K-Y (vL1) generated in step S1506, and as shown in the bottom row of FIG. vH2, vL2) is generated (step S1508). Then, the 5-3 conversion unit 38 outputs 2K-Y (hH2, vH2, vL2) to the framing header addition unit 30c.

  The framing header adding unit 30c inputs 2K-Y (hH2, vH2, vL2) from the 5-3 converting unit 38 and adds a framing header such as a multicast address. Then, the packet transmitting unit 31c generates a 2K-Y (hH2, vH2, vL2) packet to which the framing header is added, and transmits the packet (steps S1509 and S1510).

  The 5-3 conversion unit 35b inputs 8K-UV (hL1) from the YUV classification unit 37. Then, the 5-3 conversion unit 35b performs the same processing as steps S1407 and S1408 of FIG. 14 to generate 4K-UV (vH1, vL1) and 4K-UV (hH2, vH2, vL2) ( Steps S1511, S1512). The framing header addition unit 30c and the packet transmission unit 31c perform the same processing as step S1409 in FIG. 14 (step S1513). As a result, 4K-UV (hH2, vH2) packets are transmitted.

  The 5-3 conversion unit 35b performs 5-3 conversion in the horizontal and vertical directions based on 4K-UV (vL2) to generate 2K-UV (hH3, vH3, vL3) (step S1514). Then, the 5-3 conversion unit 35b outputs 2K-UV (hH3, vH3, vL3) to the framing header addition unit 30c.

  The framing header adding unit 30c inputs 2K-UV (hH3, vH3, vL3) from the 5-3 converting unit 35b and adds a framing header such as a multicast address. Then, the packet transmission unit 31c generates a 2K-UV (hH3, vH3, vL3) packet to which the framing header is added, and transmits the packet (steps S1515 and S1516).

  In this way, the packet transmitter 31c of the 30, 60, 120 Hz frame processor 19 outputs 2K-Y (hH2, vH2, vL2), 2K-UV (hH3, vH3, vL3), and 4K-Y as hierarchical video signals. Packets of (hH1, vH1), 4K-UV (hH2, vH2), 12-bit data and 10-bit data are transmitted.

  As described above, according to the video signal transmission device 1-2 of the second embodiment, the RGB / YUV conversion unit 14 converts the RGB value of the original image into the YUV value to generate 8K-YUV, and 5-3 The conversion unit 15 performs 5-3 conversion in the horizontal direction based on 8K-UV to generate 8K-UV (hL1). The frame classification unit 16 classifies 8K-Y and 8K-UV (hL1) into three types of frames, 120 Hz frame, 60, 120 Hz frame, and 30, 60, 120 Hz frame.

  The 120 Hz frame processing unit 17 performs processing such as assigning a multicast address or the like to the 120 Hz frame for classification, and transmits 8K-Y and 8K-UV (hL1) packets as hierarchical video signals.

  The 60, 120 Hz frame processing unit 18 performs 12-bit data separation processing, YUV classification processing, 5-3 conversion processing, etc. on the 60, 120 Hz frame. Then, the 60, 120 Hz frame processing unit 18 transmits packets of 4K-Y (hH1, vH1, vL1), 4K-UV (hH2, vH2, vL2) and 12-bit data as hierarchical video signals.

  The 30, 60, 120 Hz frame processing unit 19 performs 12-bit data separation processing, 10-bit data separation processing, YUV classification processing, 5-3 conversion processing, etc. on 30, 60, 120 Hz frames. Then, the 30, 60, 120 Hz frame processing unit 19 outputs 2K-Y (hH2, vH2, vL2), 2K-UV (hH3, vH3, vL3), 4K-Y (hH1, vH1), 4K- as hierarchical video signals. A packet of UV (hH2, vH2), 12-bit data and 10-bit data is transmitted.

  As a result, the video signal receiving device 2-2, which will be described later, can reproduce the video of the desired resolution by receiving only the hierarchy video signal of the desired hierarchy. That is, it is not necessary to separately reproduce images of different resolutions from one video signal in which the precision of the highest resolution is maintained.

  Therefore, only the hierarchy video signal of the hierarchy corresponding to the video signal receiving device 2-2 is transmitted, and the accuracy of the video signal does not decrease. Further, since the 5-3 conversion is not a compression encoding process for removing high frequency components from the original signal, it is possible to realize low-delay transmission as compared with the case of performing the compression encoding process.

(Receiving side / Example 2)
Next, the receiving side of the second embodiment will be described. Hereinafter, three types of video signal receiving devices will be described as the receiving side of the second embodiment. For example, the first video signal receiving device is a high resolution monitor, the second video signal receiving device is a medium resolution monitor, and the third video signal receiving device is a low resolution monitor.

(First video signal receiving device)
First, the first video signal receiving device will be described. FIG. 16 is a block diagram showing a configuration example of the first video signal receiving apparatus according to the second embodiment, and FIG. 19 is a flowchart showing a processing example of the first video signal receiving apparatus according to the second embodiment. The video signal receiving device 2-2a includes a multicast packet requesting unit 23a, a packet receiving unit 24a, a data extracting unit 25a, a 5-3 reverse conversion and 10-bit restoration unit 26a, and a 5-3 reverse conversion and 12-bit restoration unit. 27 are provided.

  The multicast packet request unit 23a generates a transmission request including a multicast address for acquiring a desired high-resolution hierarchical image, and transmits the transmission request.

  The packet receiving unit 24a uses, for example, a multicast receiving function to generate the hierarchical video signal corresponding to the transmission request transmitted by the multicast packet requesting unit 23a, and the hierarchical video signal transmitted from the video signal transmitting apparatus 1-2. To receive.

  The hierarchical video signal received by the packet receiving unit 24a is a packet of 8K-Y, 8K-UV (hL1) in a 120 Hz frame, 4K-Y (hH1, vH1, vL1) in a 60, 120 Hz frame, and 4K-UV (hH2, hH2. vH2, vL2) and packets of 12-bit data, and 2K-Y (hH2, vH2, vL2), 2K-UV (hH3, vH3, vL3), and 4K-Y (hH1, vH1) in 30, 60, and 120 Hz frames. ) 4K-UV (hH2, vH2), 12-bit data and 10-bit data packet.

  The packet receiving unit 24a distinguishes the hierarchical image and the like included in the packet based on the framing header included in the packet. Then, the packet receiving unit 24a acquires the layer images of 30, 60, and 120 Hz frames, the layer images of 60 and 120 Hz frames, and the layer images of 120 Hz frames, respectively (step S1901, step S1902, step S1903). The packet receiving unit 24a outputs the layer images of 30, 60, 120 Hz frames, the layer images of 60, 120 Hz frames, etc., and the layer images of 120 Hz frames to the data extracting unit 25a.

  The data extracting unit 25a inputs the layer images of 30, 60, 120 Hz frames, the layer images of 60, 120 Hz frames, and the layer images of 120 Hz frames from the packet receiving unit 24a. Then, the data extraction unit 25a outputs the hierarchical images of 30, 60, and 120 Hz frames to the 5-3 inverse conversion and 10-bit restoration unit 26a and the 5-3 inverse conversion and 12-bit restoration unit 27. In addition, the data extraction unit 25a outputs the 60, 120 Hz frame hierarchical images and the like to the 5-3 inverse transform and 10-bit restoration unit 26a and the 5-3 inverse transform and 12-bit restoration unit 27. In addition, the data extraction unit 25 a outputs the 120 Hz frame hierarchical image to the 5-3 inverse conversion and 12-bit restoration unit 27.

(2K, 8-bit, 30Hz video playback)
The data extraction unit 25a extracts 2K-Y (vL2) and 2K-UV (vL3) from the hierarchical images of 30, 60, and 120 Hz frames as a 2K hierarchical image (step S1904). Then, the data extraction unit 25a outputs this as a 2K video signal 2K-Y (vL2), 2K-UV (vL3) (step S1905).

  As a result, the 2K video signals 2K-Y (vL2) and 2K-UV (vL3) are used to perform 2K video display processing and the like, and 8-bit 2K video operating at a frequency of 30 Hz is reproduced. By adding 10-bit data, 2K video in 10-bit units operating at a frequency of 30 Hz may be reproduced.

(4K, 10-bit, 60Hz video playback)
The data extraction unit 25a extracts 4K-Y (vL1) and 4K-UV (vL2) as a 4K hierarchical image from the 60 and 120 Hz frame hierarchical images and the like (step S1906). Then, the data extraction unit 25a outputs the 4K-Y (vL1) and 4K-UV (vL2) of the 60 and 120 Hz frames to the 5-3 inverse conversion and 10-bit restoration unit 26a. The data extraction unit 25a also outputs the hierarchical images of 30, 60, and 120 Hz frames to the 5-3 inverse conversion and 10-bit restoration unit 26a.

  The 5-3 inverse conversion and 10-bit restoration unit 26a uses the data extraction unit 25a to perform 4K-Y (vL1) and 4K-UV (vL2) of 60,120Hz frames, and hierarchical images of 30,60,120Hz frames. Enter.

  The 5-3 inverse transform and 10-bit restoration unit 26a performs 5-3 inverse transform in the vertical and horizontal directions based on 2K-Y (hH2, vH2, vL2) for 30, 60, 120 Hz frames, and 4K-Y ( Play vL1). The 5-3 inverse conversion and 10-bit restoration unit 26a performs 5-3 inverse conversion in the vertical and horizontal directions based on 2K-UV (hH3, vH3, vL3) to reproduce 4K-UV (vL2). Then, the 5-3 inverse conversion and 10-bit restoration unit 26a adds 10-bit data to 4K-Y (vL1) and 4K-UV (vL2) to restore 10-bit data (step S1907).

  The 5-3 inverse conversion and 10-bit restoration unit 26a includes 4K-Y (vL1) and 4K-UV (vL2) for 60,120 Hz frames, and 4K-Y (vL1) and 4K-UV for 30,60,120 Hz frames. (VL2) is output as 4K video signals 4K-Y (vL1) and 4K-UV (vL2) (step S1908).

  As a result, the 4K video signals 4K-Y (vL1) and 4K-UV (vL2) are used to display the 4K video, and the 4K video in 10-bit units operating at a frequency of 60 Hz is reproduced.

(8K, 12-bit, 120Hz video playback)
The data extraction unit 25a performs 5-3 inverse conversion and 12-bit conversion on the 8K-Y and 8K-UV (hL1) that are 30, 60 and 120 Hz frames, the 60 and 120 Hz frame hierarchical images, and the 120 Hz frame hierarchical images. Output to the restoration unit 27.

  The 5-3 inverse conversion and 12-bit restoration unit 27 receives from the data extraction unit 25a 8K-Y and 8K-UV (hL1) of 120 Hz frame, hierarchical images of 60 and 120 Hz frames, and 30, 60 and 120 Hz frames. Input a hierarchical image, etc.

  The 5-3 inverse conversion and 12-bit restoration unit 27 performs the same processing as in step S1907 on the 30, 60, and 120 Hz frames to reproduce 4K-Y (vL1) and 4K-UV (vL2).

  The 5-3 inverse transform and 12-bit decompression | restoration part 27 carries out 5-horizontal-direction 5-frame based on 4K-Y (vL1) and 4K-Y (hH1, vH1) about 30,60,120Hz frame and 60,120Hz frame. 3 Reverse conversion is performed and 8K-Y is reproduced. In addition, the 5-3 inverse conversion and 12-bit restoration unit 27 performs 5-3 inverse conversion in the vertical and horizontal directions based on 4K-UV (vL2) and 4K-UV (hH2, vH2) to obtain 8K-UV (hL1). ) Is generated. Then, the 5-3 inverse conversion and 12-bit restoration unit 27 adds 12-bit data to 8K-Y and 8K-UV (hL1) and restores 12-bit data (step S1909).

  The 5-3 inverse transform and 12-bit restoration unit 27 performs 5-3 inverse transform in the horizontal direction on the basis of 8K-UV (hL1) for the 30, 60, 120 Hz frame, the 60, 120 Hz frame, and the 120 Hz frame to obtain 8K. -UV is generated (step S1910).

  The 5-3 inverse conversion and 12-bit decompression | restoration part 27 outputs 8K-YUV of a 120 Hz frame, 8K-YUV of a 60,120 Hz frame, and 8K-YUV of a 30,60,120 Hz frame as an 8K video signal 8K-YUV. Yes (step S1911).

  As a result, the 8K video signal 8K-YUV is used to perform display processing of the 8K video, etc., and 12K-unit 8K video operating at a frequency of 120 Hz is reproduced.

(Second video signal receiving device)
Next, the second video signal receiving device will be described. FIG. 17 is a block diagram showing a configuration example of the second video signal receiving apparatus according to the second embodiment, and FIG. 20 is a flowchart showing a processing example of the second video signal receiving apparatus according to the second embodiment. The video signal receiving device 2-2b includes a multicast packet requesting unit 23b, a packet receiving unit 24b, a data extracting unit 25b, and a 5-3 inverse conversion / 10-bit restoring unit 26b.

  The multicast packet request unit 23b generates a transmission request including a multicast address for acquiring a desired hierarchical image for medium resolution, and transmits the transmission request.

  The packet receiving unit 24b uses, for example, a multicast receiving function to generate a hierarchical video signal corresponding to the transmission request transmitted by the multicast packet requesting unit 23b, which is the hierarchical video signal transmitted from the video signal transmitting apparatus 1-2. To receive.

  The hierarchical video signals received by the packet receiving unit 24b are 4K-Y (hH1, vH1, vL1) and 4K-UV (hH2, vH2, vL2) packets in 60, 120 Hz frames, and 30, 60, 120 Hz frames. It is a packet of 2K-Y (hH2, vH2, vL2), 2K-UV (hH3, vH3, vL3), 4K-Y (hH1, vH1), 4K-UV (hH2, vH2) and 10-bit data.

  The packet receiving unit 24b distinguishes hierarchical images and the like based on the framing header included in the packet. Then, the packet receiving unit 24b acquires the hierarchical images of 30, 60, and 120 Hz frames, and the hierarchical images of 60 and 120 Hz frames (step S2001, step S2002). The packet receiving unit 24b outputs the layer images of 30, 60, and 120 Hz frames and the layer images of 60 and 120 Hz frames to the data extracting unit 25b.

  The data extraction unit 25b inputs the layer images of 30, 60, 120 Hz frames and the layer images of 60, 120 Hz frames from the packet reception unit 24b. Then, the data extraction unit 25b outputs the hierarchical images of 30, 60, and 120 Hz frames and the hierarchical images of 60 and 120 Hz frames to the 5-3 inverse transform and 10-bit restoration unit 26b.

(2K, 8-bit, 30Hz video playback)
The data extraction unit 25b extracts 2K-Y (vL2) and 2K-UV (vL3) as a 2K hierarchical image from the hierarchical images of 30, 60, and 120 Hz frames, as in step S1904 in FIG. Step S2003). Then, the data extraction unit 25b outputs this as the 2K video signals 2K-Y (vL2) and 2K-UV (vL3), similarly to step S1905 of FIG. 19 (step S2004).

  As a result, the 2K video signals 2K-Y (vL2) and 2K-UV (vL3) are used to perform 2K video display processing and the like, and 8-bit 2K video operating at a frequency of 30 Hz is reproduced. By adding 10-bit data, 2K video in 10-bit units operating at a frequency of 30 Hz may be reproduced.

(4K, 10-bit, 60Hz video playback)
The 5-3 inverse conversion and 10-bit decompression | restoration part 26b performs the same process as step S1907 of FIG. 19, and reproduces 4K-Y (vL1) and 4K-UV (vL2) about a 30, 60, 120 Hz frame. Then, the 5-3 inverse conversion and 10-bit restoration unit 26b adds 10-bit data to 4K-Y (vL1) and 4K-UV (vL2) to restore 10-bit data (step S2005).

  The 5-3 inverse conversion and 10-bit restoration unit 26a includes 4K-Y (vL1) and 4K-UV (vL2) for 60,120 Hz frames, and 4K-Y (vL1) and 4K-UV for 30,60,120 Hz frames. (VL2) is output as 4K video signals 4K-Y (vL1) and 4K-UV (vL2) (step S2006).

  As a result, the 4K video signals 4K-Y (vL1) and 4K-UV (vL2) are used to display the 4K video, and the 4K video in 10-bit units operating at a frequency of 60 Hz is reproduced.

(Third video signal receiving device)
Next, the third video signal receiving device will be described. FIG. 18 is a block diagram showing a configuration example of the third video signal receiving apparatus according to the second embodiment, and FIG. 21 is a flowchart showing a processing example of the third video signal receiving apparatus according to the second embodiment. The video signal receiving device 2-2c includes a multicast packet requesting unit 23c and a packet receiving unit 24c.

  The multicast packet request unit 23c generates a transmission request including a multicast address for obtaining a desired hierarchical image for low resolution, and transmits the transmission request.

  The packet receiving unit 24c uses, for example, a multicast receiving function to generate the hierarchical video signal corresponding to the transmission request transmitted by the multicast packet requesting unit 23c, and the hierarchical video signal transmitted from the video signal transmitting apparatus 1-2. To receive. Then, the packet receiving unit 24c acquires the hierarchical images of 30, 60, and 120 Hz frames (step S2101).

  The hierarchical video signals received by the packet receiving unit 24c are 2K-Y (vL2) and 2K-UV (vL3) packets in 30, 60, and 120 Hz frames.

(2K, 8-bit, 30Hz video playback)
The packet receiving unit 24c distinguishes the hierarchical image included in the packet based on the framing header included in the packet. Then, the packet receiving unit 24c, as in step S1905 of FIG. 19 and step S2004 of FIG. 20, sets the hierarchical images of 30, 60 and 120 Hz frames as 2K video signals 2K-Y (vL2) and 2K-UV (vL3). It is output (step S2102).

  As a result, the 2K video signals 2K-Y (vL2) and 2K-UV (vL3) are used to perform 2K video display processing and the like, and 8-bit 2K video operating at a frequency of 30 Hz is reproduced. When the video signal receiving device 2-2c also receives a packet of 10-bit data, the 10-bit data is added to reproduce a 2K video in 10-bit units operating at a frequency of 30 Hz. You may do it.

  As described above, according to the video signal receiving device 2-2a, 2-2b, 2-2c of the second embodiment, a packet such as a predetermined hierarchical image is received as the hierarchical video signal corresponding to the transmission request. The video signal receiving devices 2-2a, 2-2b, 2-2c operate at a frequency of 30 Hz by using the received 2K-Y (vL2) and 2K-UV (vL3) for 30, 60 and 120 Hz frames. Play 2K video in 8-bit units.

  The video signal receiving devices 2-2a and 2-2b are arranged in the vertical and horizontal directions based on the received 2K-Y (hH2, vH2, vL2) and 2K-UV (hH3, vH3, vL3) for 30, 60 and 120 Hz frames. Is subjected to 5-3 reverse conversion to reproduce 4K-Y (vL1) and 4K-UV (vL2). Then, the video signal receiving devices 2-2a and 2-2b add 10-bit data to them and restore 10-bit data. The video signal receiving devices 2-2a and 2-2b restore 4K-Y (vL1) and 4K-UV (vL2) for 30, 60 and 120 Hz frames, and 4K-Y (vL1) to receive 60 and 120 Hz frames. And 4K-UV (vL2) are used to reproduce 4K video in 10-bit units operating at a frequency of 60 Hz.

  The video signal receiving device 2-2a performs 5-3 inverse conversion in the vertical and horizontal directions on the basis of 4K-Y (vL1) and 4K-Y (hH1, vH1) for 30, 60, 120 Hz frame and 60, 120 Hz frame. And play 8K-Y. Further, the video signal receiving device 2-2a reverses 5-3 in the vertical and horizontal directions based on 4K-UV (vL2) and 4K-UV (hH2, vH2) for 30, 60, 120 Hz frame and 60, 120 Hz frame. Convert and regenerate 8K-UV (hL1). Then, the video signal receiving device 2-2a adds 12-bit data to this and restores 12-bit data.

  The video signal receiving device 2-2a performs 5-3 inverse conversion in the horizontal direction on the basis of 8K-UV (hL1) for 30, 60, 120 Hz frame, 60, 120 Hz frame, and 120 Hz frame to generate 8K-UV. To do. Then, the video signal receiving device 2-2a uses 8K-YUV for 30, 60, 120 Hz frame, 60, 120 Hz frame, and 120 Hz frame to reproduce 8K video in 12-bit unit operating at a frequency of 120 Hz.

  Thereby, the video signal receiving devices 2-2a, 2-2b, 2-2c can reproduce the video of the desired resolution by receiving only the hierarchy video signal of the desired hierarchy. That is, it is not necessary to separately reproduce images of different resolutions from one video signal in which the precision of the highest resolution is maintained.

  Therefore, only the hierarchy video signal of the hierarchy corresponding to the video signal receiving device 2-2a, 2-2b, 2-2c is transmitted, and the accuracy of the video signal does not decrease. Further, since the 5-3 conversion is not a compression encoding process for removing high frequency components from the original signal, it is possible to realize low-delay transmission as compared with the case of performing the compression encoding process.

  Further, the video signal receiving device 2-2a shown in FIG. 16 uses a 12-bit unit 8K-Y, 8K-UV (hL1) packet in a 120 Hz frame, a 60, 120 Hz frame as a hierarchical video signal corresponding to a transmission request. 10-bit unit 4K-Y (hH1, vH1, vL1), 4K-UV (hH2, vH2, vL2) and 12-bit data packets, and 8-bit unit 2K-Y in 30, 60, and 120 Hz frames. Receives packets of (hH2, vH2, vL2), 2K-UV (hH3, vH3, vL3), 4K-Y (hH1, vH1), 4K-UV (hH2, vH2), 12-bit data and 10-bit data. To do. As a result, it is possible to receive a hierarchical video signal with one 100 Gbps Ethernet.

  Further, the video signal receiving device 2-2b shown in FIG. 17 uses 4K-Y (vL1) and 4K-UV (vL2) packets in 10-bit units in 60 and 120 Hz frames as hierarchical video signals corresponding to the transmission request. , And 2K-Y (hH2, vH2, vL2), 2K-UV (hH3, vH3, vL3), 4K-Y (hH1, vH1), 4K-UV (hH2) in 8-bit 30, 60, and 120 Hz frames. , VH2) and a packet of 10-bit data are received. As a result, it is possible to receive the hierarchical video signal with one 10 Gbps Ethernet.

  Further, the video signal receiving device 2-2c shown in FIG. 18 uses 2K-Y (vL2) and 2K-UV (vL3) in 8 bit units in 30, 60 and 120 Hz frames as a hierarchical video signal corresponding to the transmission request. Receive the packet. As a result, the hierarchical video signal can be received by one 1 Gbps Ethernet.

  The video signal receiver 2-2a of the second embodiment shown in FIG. 16 reproduces 8K video, 4K video and 2K video, and the video signal receiver 2-2b shown in FIG. 17 uses 4K video and 2K video. I tried to play the video. On the other hand, the video signal receiving device 2-2a may play back only 8K video, and the video signal receiving device 2-2b may play back only 4K video. In addition, video other than 8K video, 4K video, and 2K video may be reproduced according to the hierarchical video signal of the hierarchy transmitted from the video signal transmitting apparatus 1-2.

(System / Example 2)
Next, a video signal transmitting / receiving system of the second embodiment will be described. FIG. 25 is a schematic diagram showing an example of the overall configuration of a video signal transmitting / receiving system according to the second embodiment. This video signal transmitting / receiving system includes a video signal transmitting device 1-2 shown in FIG. 9, a video signal receiving device 2-2a shown in FIG. 16, a video signal receiving device 2-2b shown in FIG. 17, and a video signal receiving device 2-2b shown in FIG. The video signal receiving device 2-2c and the router 3-2 are provided. The video signal transmitter 1-2 and the video signal receivers 2-2a, 2-2b, 2-2c are as shown in FIGS. 9 to 21.

  The router 3-2 receives a packet such as a predetermined hierarchical image as a hierarchical video signal from the video signal transmitting device 1-2, and receives a transmission request from the video signal receiving devices 2-2a, 2-2b, 2-2c. To do. Then, the router 3-2 transmits a packet such as a hierarchical image corresponding to the transmission request to the video signal receiving devices 2-2a, 2-2b, 2-2c that have transmitted the transmission request.

  As described above, according to the video signal transmission / reception system of the second embodiment, the same effect as that of the video signal transmission device 1-2 according to the second embodiment is obtained, and the video signal reception devices 2-2a, 2-2b, 2-2c. Has the same effect as. In this case, as shown in FIG. 25, the video signal transmission device 1-2 can transmit the hierarchical video signal by one 100 Gbps Ethernet. The video signal receiving device 2-2a can receive the hierarchical video signal with one 100 Gbps Ethernet. Further, the video signal receiving device 2-2b can receive the hierarchical video signal with one 10 Gbps Ethernet, and the video signal receiving device 2-2c receives the hierarchical video signal with one 1 Gbps Ethernet. be able to.

  Further, similar to the video signal transmission / reception system of the first embodiment, unlike the conventional router 104 shown in FIG. 39, the router 3-2 does not need to input video signals of different resolutions. The number of input ports and the input signal band in 2 can be reduced.

  The video signal transmission / reception system according to the second embodiment shown in FIG. 25 includes a video signal receiving device 2-2a for high resolution of 8K video and a video signal receiving device 2 for medium resolution of 4K video as a device on the receiving side. -2b and a video signal receiving device 2-2c for low resolution of 2K video. On the other hand, the video signal transmitting / receiving system may include one or two of the three video signal receiving devices 2-2a, 2-2b, 2-2c as the receiving side device. Good. Further, the video signal transmitting / receiving system may further include a video signal receiving device for other resolutions such as 1K video and 16K video. In this case, the video signal transmitting device 1-2 generates and transmits a hierarchical video signal corresponding to the resolution desired by the receiving side.

[Example 3]
Next, a third embodiment will be described. The third embodiment is an example in which the RGB uncompressed hierarchical video signals in the 8K video, the 4K video, and the 2K video are transmitted in the first embodiment, and the color depth and the frame rate are converted on the receiving side.

  In the above-described second embodiment, the video signal transmission device 1-2 shown in FIG. 9 generates a YUV 4: 2: 2 format signal, generates a hierarchical video signal from the signal of the format, and transmits the hierarchical video signal. However, in the YUV 4: 2: 2 format signal, part of the color signal information is lost from the original signal.

  On the other hand, there is known a method of converting the RGB 12-bit color depth into the RGB 10-bit color depth without distortion when converting from the BT2020 color system to the BT601 color system. Further, a technique of averaging the images before and after or smoothing by adding a prediction value is known because an image with a fast motion has a feeling of strangeness when the frame rate is simply thinned out. In the third embodiment, these existing technologies are used.

  In the third embodiment, the video signal transmission device hierarchically arranges the 8K video signal, the 4K video signal, and the 2K video signal into RGB layers, and transmits the hierarchical video signals of the respective layers. Then, the video signal receiving apparatus receives the desired hierarchical video signal and converts the color depth and the frame rate when restoring the video of the desired resolution.

(Sending side / Example 3)
First, the transmitting side of the third embodiment will be described. FIG. 26 is a block diagram showing a configuration example of a video signal transmission device according to the third embodiment. The video signal transmission device 1-3 includes original image acquisition units 10, 5-3 conversion units 40 and 41, framing header addition units 42a and 42b, and packet transmission units 43a and 43b.

  The original image acquisition unit 10 inputs a video signal to acquire an RGB4: 4: 4 format signal as an original image. The 5-3 conversion unit 40 receives the original image from the original image acquisition unit 10, performs 5-3 conversion in the horizontal and vertical directions based on the original image, as shown in FIG. (HH1, vH1, vL1) is generated. This process is the same as the 5-3 conversion process in steps S501, S502, S504, and S505 of FIG.

  The 5-3 conversion unit 40 outputs RGB (hH1, vH1) to the framing header addition unit 42a and outputs RGB (vL1) to the 5-3 conversion unit 41.

  The 5-3 conversion unit 41 inputs RGB (vL1) from the 5-3 conversion unit 40, performs 5-3 conversion in the horizontal and vertical directions based on RGB (vL1) as shown in FIG. (HH2, vH2, vL2) is generated. This process is the same as the 5-3 conversion process in steps S501, S502, S504, and S505 of FIG.

  The 5-3 conversion unit 41 outputs RGB (hH2, vH2, vL2) to the framing header addition unit 42b.

  The framing header adding unit 42a inputs RGB (hH1, vH1) from the 5-3 converting unit 40 and adds a framing header such as a multicast address to them. Then, the framing header adding section 42a outputs RGB (hH1, vH1) to which the framing header is added to the packet transmitting section 43a.

  The packet transmission unit 43a inputs RGB (hH1, vH1) to which the framing header is added from the framing header addition unit 42a, generates these packets, respectively, and transmits the RGB (hH1, vH1) packet as a hierarchical video signal. To do.

  The framing header adding unit 42b inputs RGB (hH2, vH2, vL2) from the 5-3 converting unit 41 and adds a framing header in the same manner as the framing header adding unit 42a. Then, the framing header adding unit 42b outputs the RGB (hH2, vH2, vL2) to which the framing header is added to the packet transmitting unit 43b.

  The packet transmitting unit 43b inputs the RGB (hH2, vH2, vL2) to which the framing header is added from the framing header adding unit 42b, and generates a packet like the packet transmitting unit 43a. Then, the packet transmission unit 43b transmits a packet of RGB (hH2, vH2, vL2) as a hierarchical video signal.

  In this way, the video signal transmitting apparatus 1-3 transmits RGB (hH1, vH1, hH2, vH2, vL2) packets as hierarchical video signals. RGB (hH1, vH1) is a 4K image and RGB (hH2, vH2, vL2) is a 2K image.

  The hierarchical images of RGB (hH1, vH1) and RGB (hH2, vH2, vL2) are 12-bit / 120 Hz video signals (12-bit video signals operating at a frequency of 120 Hz). This bit rate is 144 Gbps, which is the same as the original image. Therefore, these hierarchical video signals are transmitted by two 100 Gbps Ethernets or one 400 Gbps Ethernet.

  As described above, according to the video signal transmission apparatus 1-3 of the third embodiment, the 5-3 conversion units 40 and 41 perform RGB-5 (h-3) conversion based on the RGB video signal of the original image. vH1, hH2, vH2, vL2), and the packet transmission units 43a, 43b transmit RGB (hH1, vH1, hH2, vH2, vL2) packets as hierarchical video signals.

  Thereby, the video signal receiving device 2-3 described later can reproduce the video of the desired resolution by receiving only the hierarchy video signal of the desired hierarchy. That is, it is not necessary to separately reproduce images of different resolutions from one video signal in which the precision of the highest resolution is maintained.

  Therefore, only the hierarchy video signal of the hierarchy corresponding to the video signal receiving device 2-3 is transmitted, and the accuracy of the video signal does not deteriorate. Further, since the 5-3 conversion is not a compression encoding process for removing high frequency components from the original signal, it is possible to realize low-delay transmission as compared with the case of performing the compression encoding process.

(Receiving side / Example 3)
Next, the receiving side of the second embodiment will be described. Hereinafter, three types of video signal receiving devices will be described as the receiving side of the third embodiment. For example, the first video signal receiving device is a high resolution receiving device for reproducing 8K video, the second video signal receiving device is a medium resolution receiving device for reproducing 4K video, and the third video signal is received. The signal receiving device is a low resolution receiving device for reproducing 2K video.

(First video signal receiving device)
First, the first video signal receiving device will be described. FIG. 27 is a block diagram showing a configuration example of the first video signal receiving apparatus according to the third embodiment, and FIG. 30 is a flowchart showing a processing example of the first video signal receiving apparatus according to the third embodiment. The video signal receiving device 2-3a includes a multicast packet requesting unit 50a, a packet receiving unit 51a, and 5-3 inverse converting units 52 and 53.

  The multicast packet requesting unit 50a generates a transmission request including a multicast address for acquiring a high-resolution hierarchical image of 8K and transmits the transmission request.

  The packet reception unit 51a uses, for example, a multicast reception function to generate the hierarchical video signal corresponding to the transmission request transmitted by the multicast packet request unit 50a, and the hierarchical video signal transmitted from the video signal transmission device 1-3. To receive.

  The hierarchical video signal received by the packet receiving unit 51a is a packet of RGB (hH1, vH1, hH2, vH2, vL2). As described above, the bit rates of these hierarchical images are 144 Gbps, which is the same as the original images. Therefore, the video signal receiving device 2-3a can receive these hierarchical video signals via two 100 Gbps Ethernets or one 400 Gbps Ethernet.

  The packet receiving unit 51a distinguishes the hierarchical images based on the framing header included in the packet, and acquires the RGB (hH1, vH1, hH2, vH2, vL2) hierarchical images (step S3001). Then, the packet reception unit 51a outputs RGB (hH1, vH1, hH2, vH2, vL2) to the 5-3 inverse conversion unit 52.

  The 5-3 inverse conversion unit 52 inputs RGB (hH1, vH1, hH2, vH2, vL2) from the packet reception unit 51a. Then, the 5-3 inverse conversion unit 52 performs 5-3 inverse conversion in the vertical and horizontal directions based on RGB (hH2, vH2, vL2) to reproduce RGB (vL1) as shown in FIG. Step S3002). This process is the same as the 5-3 inverse transform process in steps S704 to S707 of FIG. RGB (vL1) is a video signal of 4K video in 12-bit units that operates at a frequency of 120 Hz. The 5-3 inverse conversion unit 52 outputs the reproduced RGB (vL1) and the input RGB (hH1, vH1) to the 5-3 inverse conversion unit 53.

  The 5-3 inverse conversion unit 53 inputs RGB (hH1, vH1, vL1) from the 5-3 inverse conversion unit 52. Then, as shown in FIG. 2, the 5-3 inverse conversion unit 53 performs 5-3 inverse conversion in the vertical and horizontal directions based on RGB (hH1, vH1, vL1) to reproduce the original image (step S3003). ). This process is the same as the 5-3 inverse transform process in steps S704 to S707 of FIG.

  The 5-3 inverse conversion unit 53 outputs the reproduced original image as an 8K / 12-bit / 120 Hz video signal (12-bit unit 8K video operating at a frequency of 120 Hz) (step S3004). This video signal is used for 8K satellite broadcasting and the like.

  As a result, image display processing of 8K video is performed using RGB (hH1, vH1, hH2, vH2, vL2) that is a hierarchical image of 4K, 2K / 12 bits / 120Hz, and operates at a frequency of 120Hz. 8K video in bit units is reproduced. That is, it is possible to obtain a signal with good broadcast quality.

(Second video signal receiving device)
Next, the second video signal receiving device will be described. 28 is a block diagram showing a configuration example of the second video signal receiving apparatus according to the third embodiment, and FIG. 31 is a flowchart showing a processing example of the second video signal receiving apparatus according to the third embodiment. The video signal receiving device 2-3b includes a multicast packet requesting unit 50b, a packet receiving unit 51b, a 5-3 inverse conversion unit 54, a 12/10 RGB color gamut conversion unit 55, a YUV 4: 2: 2 conversion unit 56, and a frame rate conversion. The portion 57a is provided.

  The multicast packet requesting unit 50b generates a transmission request including a multicast address for acquiring a 4K medium resolution hierarchical image, and transmits the transmission request.

  The packet receiving unit 51b uses, for example, a multicast receiving function to generate a hierarchical video signal corresponding to the transmission request transmitted by the multicast packet requesting unit 50b, which is the hierarchical video signal transmitted from the video signal transmitting apparatus 1-3. To receive.

  The hierarchical video signal received by the packet receiving unit 51b is an RGB (hH2, vH2, vL2) packet. The bit rate of the RGB (hH2) hierarchical image is about 18 Gbps, the bit rate of the RGB (vH2) hierarchical image is about 9 Gbps, and the bit rate of the RGB (vL2) hierarchical image is about 9 Gbps. The bit rate of these hierarchical images is about 36 Gbps in total. Therefore, the video signal receiving device 2-3b can receive these hierarchical video signals through one 40 Gbps Ethernet.

  The packet receiving unit 51b distinguishes hierarchical images based on the framing header included in the packet, and acquires RGB (hH2, vH2, vL2) (step S3101). Then, the packet reception unit 51b outputs RGB (hH2, vH2, vL2) to the 5-3 inverse conversion unit 54.

  The 5-3 inverse conversion unit 54 inputs RGB (hH2, vH2, vL2) from the packet reception unit 51b. Then, the 5-3 inverse conversion unit 54 performs 5-3 inverse conversion in the vertical and horizontal directions based on RGB (hH2, vH2, vL2) to reproduce RGB (vL1) as shown in FIG. Step S3102). This process is the same as the 5-3 inverse transform process in steps S704 to S707 of FIG.

  The 5-3 inverse conversion unit 54 transfers the reproduced RGB (vL1) to the 12/10 RGB color gamut conversion unit 55 as a 4K / 12-bit / 120 Hz video signal (12-bit unit 4K video operating at a frequency of 120 Hz). Output. The 12/10 RGB color gamut conversion unit 55, the YUV 4: 2: 2 conversion unit 56, and the frame rate conversion unit 57a respectively perform color gamut conversion, YUV 4: 2: 2 conversion, and frame rate conversion (step S3103).

  The 12/10 RGB color gamut conversion unit 55 inputs the 4K / 12-bit / 120 Hz video signal from the 5-3 inverse conversion unit 54, converts the color depth of RGB 12-bit to the color depth of RGB 10-bit, and outputs 4K / A video signal of 10 bits / 120 Hz is generated. Since this method of color gamut conversion is known, detailed description is omitted here. Then, the 12/10 RGB color gamut conversion unit 55 outputs the 4K / 10 bit / 120 Hz video signal to the YUV 4: 2: 2 conversion unit 56.

  The YUV 4: 2: 2 conversion unit 56 inputs the 4K / 10-bit / 120 Hz video signal from the 12/10 RGB color gamut conversion unit 55, and changes the RGB value of the 4K / 10-bit / 120 Hz video signal to YUV 4: 2: 2. Convert to YUV value in format. Then, the YUV 4: 2: 2 conversion unit 56 outputs the YUV 4: 2: 2 converted video signal of 4K / 10 bits / 120 Hz to the frame rate conversion unit 57a.

  The frame rate conversion unit 57a inputs the 4K / 10-bit / 120 Hz video signal after YUV 4: 2: 2 conversion from the YUV 4: 2: 2 conversion unit 56. Then, the frame rate conversion unit 57a converts the frame rate from 120 Hz to 60 Hz, and generates a video signal of 4K / 10 bits / 60 Hz (4K video in 10-bit units operating at a frequency of 60 Hz). Since this frame rate conversion method is already known, detailed description is omitted here.

  The frame rate conversion unit 57a outputs a video signal of 4K / 10 bits / 60 Hz (step S3104). This video signal is used for 4K satellite broadcasting, IPTV and the like.

  As a result, image display processing of 4K video is performed using RGB (hH2, vH2, vL2), which is a hierarchical image of 2K / 12 bits / 120 Hz, and a 10-bit unit 4K video operating at a frequency of 60 Hz is displayed. Is played. That is, it is possible to obtain a signal with good broadcast quality.

(Third video signal receiving device)
Next, the third video signal receiving device will be described. 29 is a block diagram showing a configuration example of the third video signal receiving apparatus according to the third embodiment, and FIG. 32 is a flowchart showing a processing example of the third video signal receiving apparatus according to the third embodiment. The video signal receiving device 2-3c includes a multicast packet requesting unit 50c, a packet receiving unit 51c, a 12/8 RGB color gamut conversion unit 58, a YUV 4: 2: 0 conversion unit 59, and a frame rate conversion unit 57b.

  The multicast packet request unit 50c generates a transmission request including a multicast address for acquiring a 2K low-resolution hierarchical image, and transmits the transmission request.

  The packet receiving unit 51c uses, for example, a multicast receiving function to generate the hierarchical video signal corresponding to the transmission request transmitted by the multicast packet requesting unit 50c, and the hierarchical video signal transmitted from the video signal transmitting apparatus 1-3. To receive.

  The hierarchical video signal received by the packet receiving unit 51c is an RGB (vL2) packet. The bit rate of RGB (vL2) is about 9 Gbps. Therefore, the video signal receiving device 2-3c can receive this hierarchical video signal by one 10 Gbps Ethernet.

  The packet receiving unit 51c distinguishes the hierarchical image based on the framing header included in the packet and acquires RGB (vL2) (step S3201).

  The packet receiving unit 51c outputs the acquired RGB (vL2) to the 12/8 RGB color gamut conversion unit 58 as a 2K / 12-bit / 120 Hz video signal (12-bit unit 2K video operating at a frequency of 120 Hz). The 12/8 RGB color gamut conversion unit 58, the YUV 4: 2: 0 conversion unit 59, and the frame rate conversion unit 57b respectively perform color gamut conversion, YUV 4: 2: 0 conversion, and frame rate conversion (step S3202).

  The 12/8 RGB color gamut conversion unit 58 inputs the video signal of 2K / 12 bits / 120 Hz from the packet reception unit 51c, converts the color depth of RGB 12 bits into the color depth of RGB 8 bits, and outputs 2K / 8 bits /. A 120 Hz video signal is generated. Since this method of color gamut conversion is known, detailed description is omitted here. Then, the 12/8 RGB color gamut conversion unit 58 outputs the 2K / 8 bit / 120 Hz video signal to the YUV 4: 2: 0 conversion unit 59.

  The YUV 4: 2: 0 conversion unit 59 inputs the 2K / 8 bit / 120 Hz video signal from the 12/8 RGB color gamut conversion unit 58, and outputs the RGB value of the 2K / 8 bit / 120 Hz video signal to YUV 4: 2: 0. Convert to YUV value in format. Then, the YUV 4: 2: 0 conversion section 59 outputs the 2K / 8 bit / 120 Hz video signal after YUV 4: 2: 0 conversion to the frame rate conversion section 57b.

  The frame rate conversion unit 57b inputs the 2K / 8 bit / 120 Hz video signal after YUV 4: 2: 0 conversion from the YUV 4: 2: 0 conversion unit 59. Then, the frame rate conversion unit 57b converts the frame rate from 120 Hz to 30 Hz, and generates a video signal of 2K / 8 bits / 30 Hz (2K video in 8-bit units operating at a frequency of 30 Hz). Since this frame rate conversion method is already known, detailed description is omitted here.

  The frame rate conversion unit 57b outputs a 2K / 8 bit / 30 Hz video signal (step S3203). This video signal is used for terrestrial digital broadcasting and the like.

  As a result, image display processing of 2K video is performed using RGB (vL2) that is a hierarchical image of 2K / 12 bits / 120 Hz, and 2K video in 8-bit units operating at a frequency of 30 Hz is reproduced and broadcast. A signal with good quality can be obtained.

  As described above, according to the video signal receiving devices 2-3a, 2-3b, 2-3c of the third embodiment, the packet of the predetermined hierarchical image is received as the hierarchical video signal corresponding to the transmission request. The video signal receiving device 2-3a performs 5-3 inverse conversion twice based on RGB (hH1, vH1, hH2, vH2, vL2) to reproduce the original image, and outputs an 8K / 12-bit / 120Hz video signal. Output.

  The video signal receiving device 2-3b performs 5-3 inverse conversion once based on RGB (hH2, vH2, vL2) and reproduces RGB (vL1) which is a hierarchical image of 4K / 12 bits / 120 Hz. Then, the video signal receiving device 2-3b performs the color gamut conversion of the RGB 12-bit color depth into the RGB 10-bit color depth, converts the RGB value into the YUV value of the YUV 4: 2: 2 format, and sets the frame rate from 120 Hz to 60 Hz. Convert to. The video signal receiving device 2-3b reproduces a 4K / 10 bit / 60 Hz video signal and outputs the video signal.

  The video signal receiving device 2-3c performs color gamut conversion of RGB 12-bit color depth into RGB 8-bit color depth for RGB (vL2), converts RGB values into YUV values in YUV 4: 2: 0 format, and sets the frame rate. Is converted from 120 Hz to 30 Hz. The video signal receiving device 2-3c reproduces a 2K / 8 bit / 30 Hz video signal and outputs the video signal.

  Thereby, the video signal receiving devices 2-3a, 2-3b, 2-3c can reproduce the video of the desired resolution by receiving only the hierarchy video signal of the desired hierarchy. That is, it is not necessary to separately reproduce images of different resolutions from one video signal in which the precision of the highest resolution is maintained.

  Therefore, only the hierarchy video signal of the hierarchy corresponding to the video signal receiving devices 2-3a, 2-3b, 2-3c is transmitted, and the accuracy of the video signal does not decrease. Further, since the 5-3 conversion is not a compression encoding process for removing high frequency components from the original signal, it is possible to realize low-delay transmission as compared with the case of performing the compression encoding process.

  The video signal receiving apparatus 2-3a of the third embodiment shown in FIG. 27 reproduces only 8K video, and the video signal receiving apparatus 2-3b shown in FIG. 28 reproduces only 4K video. .. On the other hand, the video signal receiving device 2-3a may reproduce not only 8K video but also 4K video and 2K video. In this case, the video signal receiving device 2-3a further includes the 5-3 inverse conversion unit 54, the 12/10 RGB color gamut conversion unit 55, the YUV 4: 2: 2 conversion unit 56, the frame rate conversion unit 57a, and the 12/8 RGB color. An area conversion unit 58, a YUV 4: 2: 0 conversion unit 59, and a frame rate conversion unit 57b are provided. Further, the video signal receiving device 2-3b may reproduce 2K video in addition to 4K video. In this case, the video signal receiving device 2-3b further includes a 12/8 RGB color gamut conversion unit 58, a YUV 4: 2: 0 conversion unit 59, and a YUV 4: 2: 0 conversion unit 59b. In addition, video other than 8K video, 4K video, and 2K video may be played back according to the hierarchical video signal of the hierarchy transmitted from the video signal transmitting apparatus 1-3.

(System / Example 3)
Next, a video signal transmitting / receiving system according to the third embodiment will be described. FIG. 33 is a schematic diagram showing an example of the overall configuration of a video signal transmitting / receiving system according to the third embodiment. This video signal transmitting / receiving system includes a video signal transmitting apparatus 1-3 shown in FIG. 26, a video signal receiving apparatus 2-3a shown in FIG. 27, a video signal receiving apparatus 2-3b shown in FIG. 28, and a video signal receiving apparatus 2-3b shown in FIG. The video signal receiving device 2-3c and the router 3-3 are provided. The video signal transmitter 1-3 and the video signal receivers 2-3a, 2-3b, 2-3c are as shown in FIGS. 26 to 32.

  The video signal transmission / reception system shown in FIG. 33 performs conversion of color gamut, frame rate, and the like on the reception side, and reproduces a 4K / 10 bit / 60 Hz video signal and a 2K / 8 bit / 30 Hz video signal, It provides good image quality even for typical broadcasting systems.

  The router 3-3 receives a packet of a predetermined hierarchical image as a hierarchical video signal from the video signal transmitting device 1-3, and receives a transmission request from the video signal receiving devices 2-3a, 2-3b, 2-3c. .. Then, the router 3-3 transmits the packet of the hierarchical image corresponding to the transmission request to the video signal receiving devices 2-3a, 2-3b, 2-3c that have transmitted the transmission request.

  As described above, according to the video signal transmission / reception system of the third embodiment, the same effect as that of the video signal transmission device 1-3 according to the third embodiment is obtained, and the video signal reception devices 2-3a, 2-3b, 2-3c. Has the same effect as. As shown in FIG. 33, the video signal transmitting apparatus 1-3 transmits a hierarchical video signal using two 100 Gbps Ethernets or one 400 Gbps Ethernet. The video signal receiving device 2-3a can receive the hierarchical video signal via two 100 Gbps Ethernets or one 400G Ethernet. The video signal receiving device 2-3b can receive the hierarchical video signal with one 40 Gbps Ethernet, and the video signal receiving device 2-3c can receive the hierarchical video signal with one 10 Gbps Ethernet. be able to.

  Further, similar to the video signal transmitting / receiving system of the first and second embodiments, unlike the conventional router 104 shown in FIG. 39, the router 3-3 does not need to input video signals of a plurality of different resolutions. The number of input ports and the input signal band in 3-3 can be reduced.

  The video signal transmission / reception system of the third embodiment shown in FIG. 33 includes a video signal reception device 2-3a for high resolution of 8K video and a video signal reception device 2 for medium resolution of 4K video as a device on the receiving side. -3b and a video signal receiving device 2-3c for low resolution of 2K video. On the other hand, the video signal transmitting / receiving system may include one or two of the three video signal receiving devices 2-3a, 2-3b, and 2-3c as the receiving side device. Good. Further, the video signal transmitting / receiving system may further include a video signal receiving device for other resolutions such as 1K video and 16K video. In this case, the video signal transmitting device 1-3 generates and transmits a hierarchical video signal corresponding to the resolution desired by the receiving side.

[Example 4]
Next, a fourth embodiment will be described. Example 4 is an application example of Examples 1 to 3, and in addition to 5-3 conversion (5-3 conversion in the resolution direction) in Examples 1 to 3, 5-3 conversion in the time axis direction (frame direction). Is an example of transmitting uncompressed hierarchical video signals of 8K video, 4K video, and 2K video using.

  FIG. 34 is a diagram illustrating a hierarchical process by performing 5-3 conversion in the time axis direction in the fourth embodiment. In FIG. 34, the squares of the 120 Hz original image frame, the 60 Hz low-pass frame and the 30 Hz low-pass frame indicate each frame on the time axis. In the 120 Hz original image frame, the 120 Hz, 60 Hz 120 Hz, and 30 Hz 60 Hz 120 Hz frames within the square correspond to the 120 Hz frame, 60, 120 Hz frame, and 30, 60, 120 Hz frame shown in FIG. 23, respectively.

  In the fourth embodiment, the wavelet 5-3 one-dimensional reversible conversion method is applied in the time axis direction. The low-pass filter processes the pixels at the same pixel positions in the three 120 Hz original image frames to generate one frame. This makes it possible to obtain a 60 Hz low-pass frame (60 Hz L) having a frame frequency of 1/2 with respect to the 120 Hz original image frame. In this case, in the process of generating the 60 Hz low-pass frame (60 Hz L), the same number of high-pass frames as the low-pass frames are generated by the high-pass filter.

  Furthermore, the low-pass filter processes pixels at the same pixel position in the three 60 Hz low-pass frames to generate one frame. This makes it possible to obtain a 30 Hz low-pass frame (30 Hz H, L) having a frame frequency of 1/4 with respect to the 120 Hz original image frame. In this case, in the process of generating a 30 Hz low-pass frame (30 Hz L), the same number of high-pass frames as low-pass frames are generated by the high-pass filter.

(Sender / Example 4)
First, the transmitting side of the fourth embodiment will be described. FIG. 35 is a block diagram showing a configuration example of the video signal transmitting apparatus according to the fourth embodiment, and FIG. 36 is a flowchart showing a processing example of the video signal transmitting apparatus according to the fourth embodiment. The video signal transmitting device 1-4 includes original image acquisition units 10, 5-3 conversion units 60, 62, time direction 5-3 conversion units 61, 63, framing header addition units 64a, 64b, 64c, 64d and packet transmission. The parts 65a, 65b, 65c and 65d are provided.

  The original image acquisition unit 10 inputs a video signal to acquire an RGB4: 4: 4 format signal that is an original image of a 120 Hz original image frame. The 5-3 conversion unit 60 receives the original image from the original image acquisition unit 10, performs 5-3 conversion in the horizontal and vertical directions based on the original image, as shown in FIG. (HH1, vH1, vL1) is generated (step S3601). This results in 120 Hz hH1, vH1 and vL1. The 5-3 conversion by the 5-3 conversion unit 60 and the 5-3 conversion unit 62 described later is 5-3 conversion in the resolution direction.

  Hereinafter, the description of RGB will be deleted and described. Further, for example, hH1 and vH1 of 120 Hz are expressed as hH1, vH1 / 120 Hz. The same applies to other frequencies and other hierarchical images.

  The 5-3 conversion unit 60 outputs hH1 and vH1 / 120 Hz to the framing header addition unit 64a, and outputs vL1 / 120 Hz to the time direction 5-3 conversion unit 61.

  The framing header adding unit 64a inputs hH1 and vH1 / 120 Hz from the 5-3 converting unit 60, and adds a framing header such as a multicast address to these. Then, the packet transmitting unit 65a generates the respective hH1 and vH1 packets to which the framing header is added, and transmits the hH1 and vH1 / 120 Hz packets as the hierarchical video signal (step S3602).

  When the 5-3 conversion unit 60 completes the processing of three video signals of the original image of the 120 Hz original image frame (step S3603), the time direction 5-3 conversion unit 61 outputs the 5-3 conversion unit 60 from the 5-3 conversion unit 60. Input vL 1/120 Hz for 3 frames.

  As shown in FIG. 34, the time-direction 5-3 conversion unit 61 performs 5-3 conversion in the time direction based on vL1 / 120 Hz for three frames to generate vL1-H, L / 60 Hz (step S3604). As a result, 12-bit unit 4K video vL1-L operating at a frequency of 60 Hz is obtained (step S3605). Then, the time direction 5-3 conversion unit 61 outputs vL1-H / 60 Hz to the framing header addition unit 64b, and outputs vL1-L / 60 Hz to the 5-3 conversion unit 62.

  The framing header adding unit 64b inputs vL1-H / 60 Hz from the time direction 5-3 converting unit 61, and adds a framing header such as a multicast address to this. Then, the packet transmitting unit 65b generates a vL1-H / 60 Hz packet to which the framing header is added, and transmits the vL1-H / 60 Hz packet as a hierarchical video signal (step S3606).

  The 5-3 conversion unit 62 inputs vL1-L / 60 Hz from the time direction 5-3 conversion unit 61, performs 5-3 conversion in the horizontal and vertical directions based on vL1-L / 60 Hz, and outputs hH2, vH2, vL2. / 60 Hz is generated (step S3607). Then, the 5-3 conversion unit 62 outputs hH2, vH2 / 60 Hz to the framing header addition unit 64c, and outputs vL2 / 60 Hz to the time direction 5-3 conversion unit 63.

  The framing header adding unit 64c inputs hH2, vH2 / 60 Hz from the 5-3 converting unit 62 and adds a framing header such as a multicast address to them. Then, the packet transmission unit 65c generates a packet of hH2, vH2 / 60 Hz to which the framing header is added, and transmits the packet of hH2, vH2 / 60 Hz as a hierarchical video signal (step S3608).

  When the 5-3 conversion unit 62 completes the processing of three vL1-L of the 60 Hz low-pass frame (step S3609), the time direction 5-3 conversion unit 63 outputs three frames from the 5-3 conversion unit 62. Input vL2 / 60Hz.

  The time direction 5-3 conversion unit 63 performs 5-3 conversion in the time direction based on vL2 / 60 Hz for 3 frames, and generates vL2-H, L / 30 Hz (step S3610). As a result, vL2-L that is a 2K video in 12-bit units operating at a frequency of 30 Hz is acquired (step S3611). Then, the time direction 5-3 conversion unit 63 outputs vL2-H, L / 30 Hz to the framing header addition unit 64d.

  The framing header adding unit 64d inputs vL2-H, L / 30 Hz from the time direction 5-3 converting unit 63, and adds a framing header such as a multicast address to these. Then, the packet transmission unit 65d generates a vL2-H, L / 30 Hz packet to which the framing header is added, and transmits the vL2-H, L / 30 Hz packet as a hierarchical video signal (steps S3612, S3613). ..

  As described above, according to the video signal transmission device 1-4 of the fourth embodiment, the 5-3 conversion unit 60 generates hH1, vH1, vL1 / 120 Hz by 5-3 conversion in the resolution direction. Then, the packet transmission unit 65a transmits packets of hH1 and vH1 / 120 Hz as the hierarchical video signal. The time direction 5-3 conversion unit 61 generates vL1-H, L / 60 Hz by the time direction 5-3 conversion, and the packet transmission unit 65b transmits the vL1-H / 60 Hz packet as a hierarchical video signal. ..

  The 5-3 conversion unit 62 generates hH2, vH2, vL2 / 60Hz by 5-3 conversion in the resolution direction, and the packet transmission unit 65c transmits a packet of hH2, vH2 / 60Hz as a hierarchical video signal. The time direction 5-3 conversion unit 63 generates vL2-H, L / 30 Hz by the time direction 5-3 conversion, and the packet transmission unit 65d generates the vL2-H, L / 30 Hz packet as a hierarchical video signal. Send.

  As a result, the video signal transmission device 1-4 combines the 5-3 conversion in the resolution direction and the 5-3 conversion in the time direction to obtain a hierarchical video signal of 120K 8K video, 60Hz 4K video, and 30Hz 2K video. Can be sent. Then, the video signal receiving device 2-4, which will be described later, can reproduce the desired video by receiving only the hierarchical video signal of the desired hierarchy. That is, it is not necessary to separately reproduce images of different resolutions from one video signal in which the precision of the highest resolution is maintained.

  Therefore, only the hierarchy video signal of the hierarchy corresponding to the video signal receiving device 2-4 is transmitted, and the accuracy of the video signal does not decrease. Further, since the 5-3 conversion is not a compression encoding process for removing high frequency components from the original signal, it is possible to realize low-delay transmission as compared with the case of performing the compression encoding process.

(Receiving side / Example 4)
Next, the receiving side of the fourth embodiment will be described. FIG. 37 is a block diagram showing a configuration example of the video signal receiving device according to the fourth embodiment, and FIG. 38 is a flowchart showing a processing example of the video signal receiving device according to the fourth embodiment. The video signal receiving device 2-4 includes a multicast packet requesting unit 70, a packet receiving unit 71, color gamut conversion units 72 and 75, time direction 5-3 inverse conversion units 73 and 76, and 5-3 inverse conversion unit 74. Equipped with 77.

  The multicast packet request unit 70 generates a transmission request including a multicast address for acquiring a predetermined layer image, and transmits the transmission request. Here, it is assumed that a transmission request including a multicast address for obtaining hierarchical images of 8K video, 4K video, and 2K video is generated and transmitted.

  The packet receiving unit 71 uses the multicast receiving function, for example, to receive the hierarchical video signal corresponding to the transmission request transmitted by the multicast packet requesting unit 70, and the hierarchical video signal transmitted from the video signal transmitting device 1-4. To receive.

  The hierarchical video signals received by the packet receiving unit 71 are a packet of hH1, vH1 / 120 Hz, a packet of vL1-H, hH2, vH2 / 60 Hz, and a packet of vL2-H, L / 30 Hz.

  The packet receiving unit 71 distinguishes between hH1, vH1 / 120Hz, vL1-H, hH2, vH2 / 60Hz, and vL2-H, L / 30Hz based on the framing header included in the packet, and vL2-H, L / 30Hz. 30 Hz is acquired (step S3801). The packet receiving unit 71 outputs vL2-L / 30 Hz to the color gamut conversion unit 72, and outputs vL2-H / 30 Hz to the time direction 5-3 inverse conversion unit 73.

  The color gamut conversion unit 72 inputs vL2-L / 30 Hz from the packet reception unit 71, and performs color gamut conversion from RGB 12-bit color depth to RGB 8-bit color depth and YUV 4: 2: 0 conversion ( Step S3802). This processing is the same as the processing of the 12/8 RGB color gamut conversion unit 58 and the YUV 4: 2: 0 conversion unit 59 of FIG. The color gamut conversion unit 72 generates and outputs a 2K / 8 bit / 30 Hz video signal (step S3803).

  As a result, video display processing of 2K video is performed using vL2-L / 30Hz in 12-bit units, and 2K video in 8-bit units operating at a frequency of 30Hz is reproduced, and a signal with good broadcast quality is obtained. Obtainable.

  When the packet receiving unit 71 completes the processing of three 30 V low-pass frames of vL2-H, L / 30 Hz (step S3804), the time direction 5-3 inverse transforming unit 73 causes the packet receiving units 71 to 3 Input vL2-H, L / 30 Hz for the frame.

  As shown in FIG. 34, the time direction 5-3 inverse conversion unit 73 performs 5-3 inverse conversion in the time direction based on vL2-H, L / 30 Hz for three frames to reproduce vL2 / 60 Hz. (Step S3805). Then, the time direction 5-3 inverse transformation unit 73 outputs vL2 / 60 Hz to the 5-3 inverse transformation unit 74.

  The packet receiving unit 71 acquires hH2, vH2 / 60 Hz by distinguishing the hierarchical images based on the framing header (step S3806), and outputs hH2, vH2 / 60 Hz to the 5-3 inverse conversion unit 74.

  The 5-3 inverse conversion unit 74 inputs vL2 / 60 Hz from the time direction 5-3 inverse conversion unit 73, and inputs hH2 and vH2 / 60 Hz from the packet reception unit 71. Then, the 5-3 inverse conversion unit 74 performs 5-3 inverse conversion in the vertical and horizontal directions based on hH2, vH2, vL2 / 60 Hz to reproduce vL1 / 60 Hz (step S3807). The 5-3 inverse conversion unit 74 outputs vL1 / 60 Hz to the color gamut conversion unit 75 and the time direction 5-3 inverse conversion unit 76.

  The color gamut conversion unit 75 inputs vL1 / 60 Hz from the 5-3 inverse conversion unit 74, and performs color gamut conversion from RGB 12-bit color depth to RGB 10-bit color depth and YUV 4: 2: 2 conversion, respectively. (Step S3808). This process is the same as the process of the 12/10 RGB color gamut conversion unit 55 and the YUV 4: 2: 2 conversion unit 56 of FIG. The color gamut conversion unit 75 generates and outputs a 4K / 10 bit / 60 Hz video signal (step S3809).

  As a result, video display processing of 4K video is performed using hH2, vH2 / 60Hz and vL2-H, L / 30Hz in 12-bit units, and 4K video in 10-bit units operating at a frequency of 60Hz is reproduced. As a result, a good signal can be obtained as the broadcast quality.

  The packet receiving unit 71 completes the processing for three vL1-H / 60 Hz 60 Hz low-pass frames, and the 5-3 inverse conversion unit 74 completes the processing for three vL1 / 60 Hz frames. (Step S3810). Then, the time direction 5-3 reverse conversion unit 76 inputs vL1-H / 60 Hz for 3 frames from the packet reception unit 71, and inputs vL1 / 60 Hz for 3 frames from the 5-3 reverse conversion unit 74.

  As shown in FIG. 34, the time direction 5-3 inverse conversion unit 76 performs 5-3 inverse conversion in the time direction based on vL1-H / 60 Hz and vL1 / 60 Hz for three frames to obtain vL1 / 120 Hz. Playback is performed (step S3811). Then, the time direction 5-3 inverse conversion unit 76 outputs vL1 / 120 Hz to the 5-3 inverse conversion unit 77.

  When the packet receiving unit 71 acquires hH1 and vH1 / 120 Hz (step S3812), the 5-3 inverse conversion unit 77 inputs hH1 and vH1 / 120 Hz from the packet receiving unit 71. Further, the 5-3 inverse conversion unit 77 inputs vL1 / 120 Hz from the time direction 5-3 inverse conversion unit 76. Then, the 5-3 inverse conversion unit 77 performs 5-3 inverse conversion in the vertical and horizontal directions based on hH1, vH1, and vL1 / 120 Hz to reproduce the original image (step S3813).

  The 5-3 inverse conversion unit 77 outputs the reproduced original image as a video signal of 8K / 12 bits / 120 Hz (step S3814).

  As a result, the video display processing of 8K video is performed using the 12-bit unit hH1, vH1 / 120 Hz, vL1-H, hH2, vH2 / 60 Hz, and vL2-H, L / 30 Hz, and at a frequency of 120 Hz. An operating 8K video in 12-bit units is reproduced. That is, it is possible to obtain a signal with good broadcast quality.

  As described above, according to the video signal receiving device 2-4 of the fourth embodiment, as the hierarchical video signal corresponding to the transmission request, a packet of hH1, vH1 / 120 Hz, a packet of vL1-H, hH2, vH2 / 60 Hz, and vL2-H, L / 30 Hz packet is received. Then, the video signal receiving device 2-4 performs 5-3 reverse conversion in the resolution direction twice based on hH1, vH1 / 120 Hz, vL1-H, hH2, vH2 / 60 Hz, and vL2-H, L / 30 Hz. The original image is reproduced by performing 5-3 inverse transformation in the time direction twice. The video signal receiving device 2-4 outputs this as a video signal of 8K / 12 bits / 120 Hz.

  The video signal receiving device 2-4 uses the vL1-H, hH2, vH2 / 60 Hz, and vL2-H, L / 30 Hz to perform 5-3 reverse conversion in the resolution direction once and 5-time reverse conversion in the time direction. 3 Inverse conversion is performed and vL1 / 60 Hz is reproduced. Then, the video signal receiving device 2-4 converts the color gamut and the like, reproduces a 4K / 10 bit / 60 Hz video signal, and outputs the video signal.

  The video signal receiving device 2-4 converts the color gamut or the like for vL2-L / 30 Hz, reproduces a 2K / 8 bit / 30 Hz video signal, and outputs the video signal.

  As a result, the video signal receiving device 2-4 can reproduce the video of the desired resolution by receiving only the hierarchy video signal of the desired hierarchy. That is, it is not necessary to separately reproduce images of different resolutions from one video signal in which the precision of the highest resolution is maintained.

  Therefore, only the hierarchy video signal of the hierarchy corresponding to the video signal receiving device 2-4 is transmitted, and the accuracy of the video signal does not decrease. Further, since the 5-3 conversion is not a compression encoding process for removing high frequency components from the original signal, it is possible to realize low-delay transmission as compared with the case of performing the compression encoding process.

  The video signal receiving apparatus 2-4 of the third embodiment shown in FIG. 37 is adapted to reproduce 8K video, 4K video and 2K video. On the other hand, the video signal receiving device 2-4 may reproduce one or two videos of 8K video, 4K video, and 2K video. In addition, video other than 8K video, 4K video, and 2K video may be played back according to the hierarchical video signal of the hierarchy transmitted from the video signal transmission device 1-4.

(System / Example 4)
Next, a video signal transmitting / receiving system according to the fourth embodiment will be described. This video signal transmission / reception system is similar to the configuration example of the video signal transmission / reception system according to the third embodiment shown in FIG. 33, and the video signal transmission device 1-4 and the video signal reception devices 2-4a, 2- shown in FIG. 4b, 2-4c and a router. The video signal receiving devices 2-4a, 2-4b, 2-4c correspond to the video signal receiving device 2-4 shown in FIG.

  In this video signal transmitting / receiving system, the transmitting side performs 5-3 conversion in the resolution direction and the time direction, and the receiving side performs 5-3 inverse conversion in the resolution direction and the time direction and color gamut conversion. Then, the receiving side reproduces a video signal of 8K / 12 bits / 120 Hz, a video signal of 4K / 10 bits / 60 Hz, and a video signal of 2K / 8 bits / 30 Hz, which is good even for a typical broadcasting system. Provides excellent image quality.

  The configuration of the video signal transmitting device 1-4 is as shown in FIG. 35, and the processing is as shown in FIG. 36. The video signal receiving device 2-4a receives hierarchical video signals of 8K video, 4K video, and 2K video, and outputs a video signal of 8K / 12 bits / 120Hz, a video signal of 4K / 10bits / 60Hz, and 2K / 8bits. Reproduce a / 30Hz video signal. The configuration of the video signal receiving device 2-4a is as shown in FIG. 37, and the processing is as shown in FIG.

  The video signal receiving device 2-4b receives the 4K video and the hierarchical video signal of the 2K video, and reproduces the 4K / 10 bit / 60 Hz video signal and the 2K / 8 bit / 30 Hz video signal. The video signal receiving device 2-4b includes a multicast packet requesting unit 70, a packet receiving unit 71, color gamut conversion units 72 and 75, and a time direction 5-3 inverse conversion units 73 and 5-in the configuration shown in FIG. The three-inverse conversion unit 74 is provided. The video signal receiving device 2-4b performs the processes of steps S3801 to S3809 among the processes shown in FIG.

  The multicast packet requesting unit 70 of the video signal receiving device 2-4b generates a transmission request including a multicast address for acquiring a hierarchical image of 4K video and 2K video, and transmits the transmission request. Then, the packet receiving unit 71 receives vL1-H, hH2, vH2 / 60 Hz packets and vL2-H, L / 30 Hz packets as hierarchical video signals from the video signal transmission device 1-4 via the router. To do.

  The video signal receiving device 2-4c receives the hierarchical video signal of 2K video and reproduces the video signal of 2K / 8 bits / 30 Hz. The video signal receiving device 2-4c includes a multicast packet requesting unit 70, a packet receiving unit 71, and a color gamut conversion unit 72 in the configuration shown in FIG. The video signal receiving device 2-4c performs the process of step S3801, which acquires vL2-L / 30 Hz, and the processes of steps S3802 and S3803 among the processes shown in FIG.

  The multicast packet requesting unit 70 of the video signal receiving device 2-4c generates a transmission request including a multicast address for acquiring a hierarchical image of 2K video, and transmits the transmission request. Then, the packet receiving unit 71 receives a packet of vL2-L / 30 Hz as a hierarchical video signal from the video signal transmitting device 1-4 via the router.

  The router receives packets of hierarchical images of 8K video, 4K video, and 2K video as hierarchical video signals from the video signal transmitting device 1-4 and transmits them from the video signal receiving devices 2-4a, 2-4b, 2-4c. Receive the request. Then, the router transmits the packet of the hierarchical image corresponding to the transmission request to the video signal receiving devices 2-4a, 2-4b, 2-4c that have transmitted the transmission request.

  As described above, according to the video signal transmitting / receiving system of the fourth embodiment, the same effects as those of the video signal transmitting device 1-4 and the video signal receiving device 2-4 according to the fourth embodiment are obtained. Further, as in the third embodiment, the video signal transmission device 1-4 transmits the hierarchical video signal via two 100 Gbps Ethernet or one 400 Gbps Ethernet. Then, the video signal receiving device 2-4a can receive the hierarchical video signal through two 100 Gbps Ethernets or one 400G Ethernet. Further, the video signal receiving device 2-4b can receive the hierarchical video signal on one 40 Gbps Ethernet, and the video signal receiving device 2-4c can receive the hierarchical video signal on one 10 Gbps Ethernet. be able to.

  Further, similar to the video signal transmitting / receiving system of the first, second, and third embodiments, unlike the conventional router 104 shown in FIG. 39, the router does not need to input video signals of different resolutions. The number of input ports and the input signal band can be reduced.

  The video signal transmitting / receiving system according to the fourth exemplary embodiment includes, as devices on the receiving side, a video signal receiving device 2-4a for high resolution of 8K video, a video signal receiving device 2-4b for medium resolution of 4K video, and 2K. It is configured to include a video signal receiving device 2-4c for low resolution video. On the other hand, the video signal transmitting / receiving system may include one or two of the three video signal receiving devices 2-4a, 2-4b, 2-4c as the receiving side device. Good. Further, the video signal transmitting / receiving system may further include a video signal receiving device for other resolutions such as 1K video and 16K video. In this case, the video signal transmitting device 1-3 generates and transmits a hierarchical video signal corresponding to the resolution desired by the receiving side.

1, 101 Video signal transmission device 2, 105 Video signal reception device 3, 104 Router 10 Original image acquisition unit 11, 15, 34, 35, 38, 40, 41, 60, 62 5-3 conversion unit 12, 30, 42 , 64 Framing header addition unit 13, 31, 43, 65 Packet transmission unit 14 RGB / YUV conversion unit 16 Frame classification unit 17 120Hz frame processing unit 1860, 120Hz frame processing unit 19 30, 60, 120Hz frame processing unit 20, 24 , 51, 71 packet receiving unit 21, 25 data extracting unit 22, 52, 53, 54, 74, 77 5-3 inverse converting unit 23, 50, 70 multicast packet requesting unit 26 5-3 inverse converting and 10-bit restoring unit 27 5-3 Inverse conversion and 12-bit restoration section 32, 36 Data separation section 33, 37 YUV classification section 55 12/1 RGB color gamut conversion unit 56 YUV 4: 2: 2 conversion unit 57 frame rate conversion unit 58 12/8 RGB color gamut conversion unit 59 YUV 4: 2: 0 conversion unit 61, 63 time direction 5-3 conversion unit 72, 75 color gamut, etc. Converters 73 and 76 Time direction 5-3 Inverse converter 102 Distributor 103 Down converter

Claims (6)

An RGB / YUV conversion unit that converts RGB values in a 12-bit unit 8K original image operating at 120 Hz into YUV values and generates a YUV 4: 4: 4 format signal as an 8K-YUV hierarchical image,
Based on the 8K-UV hierarchical image of the 8K-YUV hierarchical image generated by the RGB / YUV conversion unit, 5-3 conversion according to the wavelet 5-3 reversible conversion method is performed in the horizontal direction, and 8K- UV (hL1 (h indicates that horizontal 5-3 conversion has been performed, L indicates that a low-pass filter has been applied.)) A first 5-3 conversion unit that generates a hierarchical image,
An 8K-Y layer image of the 8K-YUV layer image generated by the RGB / YUV conversion unit that is a YUV 4: 2: 2 format signal, and the first 5-3 conversion unit generated For the 8K-UV (hL1) hierarchical image, a frame classification unit that classifies 120 Hz frames for 120 Hz, 60 and 120 Hz frames common to 60 Hz and 120 Hz, and 30, 60 and 120 Hz frames common to 30 Hz, 60 Hz and 120 Hz,
A 120 Hz frame processing unit, a 60, 120 Hz frame processing unit, and a 30, 60, 120 Hz frame processing unit,
The 120 Hz frame processing unit is
A first header adding unit that adds distinction information to a header for the 8K-Y hierarchical image and the 8K-UV (hL1) hierarchical image in the 120 Hz frame classified by the frame classification unit;
A first packet transmitting unit that generates a packet of each hierarchical image to which the header is added by the first header adding unit and that transmits the packet as an uncompressed hierarchical video signal,
The 60 and 120 Hz frame processing units are
Separating upper 10-bit data and lower 2-bit data from 12-bit data of the 8K-Y hierarchical image and the 8K-UV (hL1) hierarchical image in the 60, 120 Hz frame classified by the frame classification unit, An 8K-Y layer image and an 8K-UV (hL1) layer image corresponding to an 8K video in 10-bit units made of the upper 10-bit data are generated, and the lower 2-bit data is generated as 12-bit data. A first data separation unit,
Based on the first of the 8K-Y layer image generated by the data component away portion, by the 5-3 conversion, is 4K-Y (hH1 (H corresponding to 4K video 10-bit units a high-pass filter applied , VH1 (v indicates that vertical 5-3 conversion has been performed), vL1) a second 5-3 conversion unit for generating a hierarchical image,
The first of the 8K-UV (HL1) generated by the data content away section on the basis of the hierarchical image is subjected to the 5-3 conversion and YUV value conversion, 4K-UV corresponding to 4K video 10-bit units ( hH2, vH2, vL2) a third 5-3 conversion unit for generating a hierarchical image,
The first of the 12-bit data generated by the data component away portion, the second 5-3 conversion section the 4K-Y produced by (hH1, VH1, vL1) layer image, and the third A second header adding unit for adding discrimination information to a header of the 4K-UV (hH2, vH2, vL2) layer image generated by the 5-3 conversion unit;
A second packet transmitter that generates packets of the 12-bit data and the respective layer images to which the header has been added by the second header adding unit, and transmits the packets as an uncompressed layer video signal; Equipped with
The 30, 60, 120 Hz frame processing unit is
Separate upper 10-bit data and lower 2-bit data from 12-bit data of the 8K-Y hierarchical image and the 8K-UV (hL1) hierarchical image in the 30, 60, and 120 Hz frames classified by the frame classification unit. Then, the lower 2-bit data is generated as 12-bit data, the upper 8-bit data and the lower 2-bit data are separated from the higher 10-bit data, and the lower 2-bit data is converted into 10-bit data. And a second data separation unit for generating an 8K-Y hierarchical image and an 8K-UV (hL1) hierarchical image corresponding to an 8K video in 8-bit units made up of the upper 8-bit data.
Based on the second of the 8K-Y layer image generated by the data component away portion, by the 5-3 conversion, 4K-Y (hH1, vH1 ) layer image corresponding to the 4K image in units of 8 bits, and A fourth 5-3 conversion unit for generating 2K-Y (hH2, vH2, vL2) corresponding to 2K video in 8-bit units,
The second of the 8K-UV (HL1) generated by the data content away section on the basis of the hierarchical image is subjected to the 5-3 conversion and YUV value conversion, 4K-UV corresponding to 4K video in units of 8 bits ( a fifth 5-3 conversion unit for generating a 2K-UV (hH3, vH3, vL3) hierarchical image corresponding to a 2K video in 8 bit units, and an hH2, vH2) hierarchical image;
It said second of said generated by the data content away portion 12-bit data and the 10-bit data, the fourth of the 4K-Y generated by the 5-3 conversion unit (hH1, VH1) layer image and said 2K-Y (hH2, vH2, vL2), and the 4K-UV (hH2, vH2) layer image and the 2K-UV (hH3, vH3, vL3) layer image generated by the fifth 5-3 conversion unit. With respect to, a third header addition unit that adds the discrimination information to the header,
A third packet for generating the 12-bit data, the 10-bit data, and each hierarchical image to which the header is added by the third header adding unit, and transmitting the packet as an uncompressed hierarchical video signal. And a packet transmitter of
Sent by the first packet transmitter of the 120 Hz frame processor, the second packet transmitter of the 60,120 Hz frame processor, and the third packet transmitter of the 30,60,120 Hz frame processor. In the packet, a packet transmitted using 100 Gbps Ethernet to reproduce an original image of 8K video, a packet transmitted using 10 Gbps Ethernet to reproduce 4K video, and a 2K video are reproduced. The video signal transmitting apparatus is characterized in that it includes a packet transmitted by using 1 Gbps Ethernet in order to perform. Based on the original image of 8K in 12-bit units operating at 120 Hz, 5-3 conversion according to the wavelet 5-3 reversible conversion method was performed, and hH1 of 120 Hz (h was 5-3 conversion in the horizontal direction was performed. , H indicates that a high-pass filter has been applied, vH1 (v indicates that 5-3 transformation in the vertical direction has been applied), vL1 (L indicates that a low-pass filter has been applied. A first 5-3 conversion unit for generating a hierarchical image,
A first time for performing the 5-3 conversion in the time direction based on the 120 Hz vL1 layer image generated by the first 5-3 conversion unit and generating a 60 Hz vL1-H, L layer image. A direction 5-3 converter,
The second 5-3 conversion is performed on the basis of the 60 Hz vL1-L layer image generated by the first time direction 5-3 conversion unit to generate a 60 Hz hH2, vH2, vL2 layer image. 5-3 conversion unit,
Second time for performing the 5-3 conversion in the time direction based on the 60 Hz vL2 hierarchical image generated by the second 5-3 conversion unit to generate a 30 Hz vL2-H, L hierarchical image. A direction 5-3 converter,
The 120 Hz hH1, vH1 layer image generated by the first 5-3 conversion unit, the 60 Hz vL1-H layer image generated by the first time direction 5-3 conversion unit, and the second 5-3 of the 60Hz generated by varying section HH2, VH2 layer image, and the second of the 30Hz generated by the time direction 5-3 conversion section VL2-H, the L layer image, the identification information A header addition part to be added to the header,
A video signal transmitting apparatus, comprising: a packet transmitting unit that generates a packet of each hierarchical image to which the header is added by the header adding unit and transmits the packet as an uncompressed hierarchical video signal. .. A packet request unit for transmitting a transmission request for acquiring a desired hierarchical image to a router for transferring the packet transmitted from the video signal transmitting device according to claim 1 .
The 1 Gbps Ethernet is used to reproduce 2K video, the 10 Gbps Ethernet is used to reproduce 4K video, and the 100 Gbps Ethernet is used to reproduce the original 8K video image. A packet receiving unit which receives a corresponding packet from the router and distinguishes 12-bit data, 10-bit data and a hierarchical image based on the discrimination information added to the header of the packet;
At least one of a first video playback unit for playing 2K video, a second video playback unit for playing 4K video, and a third video playback unit for playing an original image of 8K video; ,,
The first video reproduction section,
The 2K-Y (vL2) layer image and the 2K-UV (vL3) layer image of 30, 60, and 120 Hz frames which are distinguished by the packet receiving unit are extracted, and the 2K-Y (vL2) layer image and the 2K-UV (VL2) layer image are extracted. vL3) A data extraction unit that outputs a hierarchical image as a video signal of an 8-bit unit 2K video operating at 30 Hz,
The second video reproduction section,
Based on the 2K-Y (hH2, vH2, vL2) layered images of 30, 60, and 120 Hz frames distinguished by the packet receiving unit, 5-3 inverse conversion according to the wavelet 5-3 reversible conversion method is performed, and 30 , 60, 120Hz frame 4K-Y (vL1) layer image is reproduced,
Based on the 2K-UV (hH3, vH3, vL3) layer image of 30, 60, 120 Hz frames distinguished by the packet receiving unit, the 5-3 inverse conversion is performed to perform 4K-UV (vL2 of 30, 60, 120 Hz frames. ) Play the hierarchical image,
The 10-bit data is added to the 4K-Y (vL1) layer image and the 4K-UV (vL2) layer image of the 30, 60 and 120 Hz frames,
The 4K-Y (vL1) layer image and the 4K-UV (vL2) layer image of the 30, 60, 120 Hz frame to which the 10-bit data is added, and the 4K of the 60, 120 Hz frame distinguished by the packet receiving unit. A 5-3 inverse conversion and 10-bit restoration unit that outputs the Y (vL1) layer image and the 4K-UV (vL2) layer image as a video signal of a 10-bit unit 4K image operating at 60 Hz,
The third video reproduction section,
4K-Y (hH1, vH1) layer images of 30, 60, 120 Hz frames distinguished by the packet receiving unit, and the 30, 60, 120 Hz frames reproduced by the 5-3 inverse transform and 10-bit restoring unit. Based on the 4K-Y (vL1) layer image of No. 10, the 8K-Y layer image of 30, 60, 120 Hz frames is reproduced by the 5-3 inverse conversion, and the 10-bit data and the 10K bit data are added to the 8K-Y layer image. Adding the 12-bit data,
4K-UV (hH2, vH2) layer images of 30, 60, 120 Hz frames distinguished by the packet receiving unit, and the 30, 60, 120 Hz frames reproduced by the 5-3 inverse transform and 10-bit restoring unit. Based on the 4K-UV (vL2) layer image of the above, the 8K-UV layer image of 30, 60, 120 Hz frames is reproduced by the 5-3 inverse conversion, and the 10-bit data and the 10K bit data are added to the 8K-UV layer image. Adding the 12-bit data,
Based on the 4K-Y (hH1, vH1, vL1) layer image of the 60, 120 Hz frame distinguished by the packet receiving unit, the 8K-Y layer image of the 60, 120 Hz frame is reproduced by the 5-3 inverse conversion. , Adding the 12-bit data to the 8K-Y hierarchical image,
Based on the 4K-UV (hH2, vH2, vL2) layer image of 60, 120Hz frame distinguished by the packet receiving unit, the 8K-UV layer image of 60, 120Hz frame is reproduced by the 5-3 inverse conversion. , Adding the 12-bit data to the 8K-UV hierarchical image,
On the basis of the 8K-UV (hL1) layer image of the 120Hz frame distinguished by the packet receiving unit, the 8K-UV layer image of the 120Hz frame is reproduced by the 5-3 inverse conversion,
An 8K-YUV hierarchical image of the 30, 60, 120 Hz frame to which the 10-bit data and the 12-bit data are added, an 8K-YUV hierarchical image of the 60, 120 Hz frame to which the 12-bit data is added, and The 8K-Y hierarchical image of 120Hz frame and the reproduced 8K-UV hierarchical image of 120Hz frame, which are distinguished by the packet receiving unit, are output as video signals of 12K-unit 8K video operating at 120Hz 5-3 Reverse A video signal receiving device comprising a conversion and 12-bit restoration unit. A video signal receiving device in a video signal transmitting / receiving system configured to include a video signal transmitting device, a router, and a video signal receiving device,
The video signal transmitting device,
Based on an 8K original image in 12-bit units operating at 120 Hz, 5-3 conversion is performed according to the wavelet 5-3 reversible conversion method, and RGB (hH1 (h is 5-3 conversion in the horizontal direction is a RGB signal. Is applied, H indicates that a high-pass filter is applied, vH1 (v indicates that 5-3 conversion in the vertical direction is applied), vL1 (L indicates a low-pass filter). It is applied.)) A first 5-3 conversion unit that generates a hierarchical image,
Based on the RGB (vL1) layer image generated by the first 5-3 conversion unit, the 5-3 conversion is performed to generate an RGB (hH2, vH2, vL2) layer image. 3 converters,
A distinction is made between the RGB (hH1, vH1) layer image generated by the first 5-3 conversion unit and the RGB (hH2, vH2, vL2) layer image generated by the second 5-3 conversion unit. A header addition section for adding information to the header,
Packets of the RGB (hH1, vH1) layer image and the RGB (hH2, vH2, vL2) layer image to which the header has been added by the header adding unit are generated, and these packets are transmitted as an uncompressed layer video signal. And a packet transmission unit,
The video signal receiving device,
To the router to forward packets sent from the video signal transmitter, and a packet request unit for transmitting a transmission request for obtaining a desired hierarchical images,
A packet receiving unit that receives a packet corresponding to the transmission request from the router and that distinguishes hierarchical images based on the identification information added to the header of the packet;
At least one video reproduction unit of a first video reproduction unit that reproduces the 8K video of the original image, a second video reproduction unit that reproduces the 4K video, and a third video reproduction unit that reproduces the 2K video. ,,
The first video reproduction section,
On the basis of the RGB (hH2, vH2, vL2) layered images discriminated by the packet receiving unit, 5-3 inverse transformation according to the wavelet 5-3 reversible transformation method is performed to reproduce the RGB (vL1) layered image, Based on the RGB (hH1, vH1) layer image and the RGB (vL1) layer image which are distinguished by the packet receiving unit, the 5-3 inverse conversion is performed, the original image is reproduced, and the original image is reproduced at 120 Hz. A first 5-3 inverse conversion unit for outputting as a video signal of an operating 8K video in 12-bit units,
The second video reproduction section,
A second 5-3 inverse transform unit that performs the 5-3 inverse transform based on the RGB (hH2, vH2, vL2) hierarchical image distinguished by the packet receiving unit and reproduces the RGB (vL1) hierarchical image; ,
For the video signal of 4K video in 12-bit units operating at 120 Hz, which is the RGB (vL1) hierarchical image reproduced by the second 5-3 conversion unit, the color depth of RGB 12-bit is converted to the color depth of RGB 10-bit. A 12/10 RGB gamut conversion unit that performs gamut conversion and generates a video signal of a 10-bit unit 4K video that operates at 120 Hz;
A YUV 4: 2: 2 conversion unit for converting RGB values into YUV values in a YUV 4: 2: 2 format for a video signal of 10-bit unit 4K video generated at the 12/10 RGB gamut conversion unit and operating at 120 Hz. When,
Regarding the video signal of 10-bit unit 4K video operating at 120 Hz, which has been converted to YUV values in the YUV 4: 2: 2 format by the YUV 4: 2: 2 conversion unit, the frame rate is converted from 120 Hz to 60 Hz, and at 60 Hz. A first frame rate conversion unit that outputs a video signal of an operating 4K video in 10-bit units,
The third video reproduction section,
For a video signal of a 2K video in 12-bit units operating at 120 Hz, which is an RGB (vL2) hierarchical image distinguished by the packet receiving unit, color gamut conversion from RGB 12-bit color depth to RGB 8-bit color depth is performed at 120 Hz. A 12/8 RGB color gamut conversion unit that generates a video signal of an operating 8-bit 2K video;
A YUV4: 0: 0 conversion unit that converts RGB values into YUV values in a YUV4: 0: 0 format for the video signal of the 8-bit unit 2K image generated at the 12/8 RGB gamut conversion unit and operating at 120 Hz. When,
The video signal of the 2K video in 8-bit units operating at 120 Hz, which has been converted into the YUV value in the YUV 4: 0: 0 format by the YUV 4: 0: 0 conversion unit, the frame rate is converted from 120 Hz to 30 Hz, and operated at 30 Hz. And a second frame rate conversion unit that outputs a video signal of 2K video in 8-bit units. A packet request unit for transmitting a transmission request for acquiring a desired hierarchical image to a router for transferring a packet transmitted from the video signal transmitting device according to claim 2 .
A packet receiving unit that receives a packet corresponding to the transmission request from the router and that distinguishes hierarchical images based on the identification information added to the header of the packet;
At least one video reproduction unit of a first video reproduction unit that reproduces the 8K video of the original image, a second video reproduction unit that reproduces the 4K video, and a third video reproduction unit that reproduces the 2K video. ,,
The first video reproduction section,
On the basis of the 30 Hz vL2-H, L layer images discriminated by the packet receiving unit, 5-3 inverse transformation according to the wavelet 5-3 reversible transformation method is performed in the time direction to reproduce a 60 Hz vL2 layer image. A first time direction 5-3 inverse transformation unit,
A wavelet 5-3 reversible transform method based on the 60 Hz hH2, vH2 hierarchical image distinguished by the packet receiving unit and the 60 Hz vL2 hierarchical image generated by the first time direction 5-3 inverse transform unit. And a first 5-3 inverse transform unit for performing a 5-3 inverse transform according to the above, and reproducing a 60 Hz vL1 layer image,
Based on the 60 Hz vL1-H layer image distinguished by the packet receiving unit and the 60 Hz vL1 layer image reproduced by the first 5-3 inverse conversion unit, the 5-3 inverse conversion is performed in the time direction. And a second time direction 5-3 inverse transformation unit that reproduces a 120-Hz vL1 hierarchical image,
The 5-3 inverse transform is performed on the basis of the 120 Hz hH1, vH1 hierarchical image distinguished by the packet receiving unit and the 120 Hz vL1 hierarchical image generated by the second time direction 5-3 inverse transforming unit. And a second 5-3 inverse conversion unit that reproduces the original image and outputs the original image as a video signal of a 12-bit unit 8K video operating at 120 Hz,
The second video reproduction section,
The first time direction 5-3 inverse transform unit, the first 5-3 inverse transform unit,
For a video signal of 4K video in 12-bit units operating at 60 Hz, which is the 60-Hz vL1 hierarchical image reproduced by the first 5-3 inverse conversion unit, RGB 12-bit color depth is converted to RGB 10-bit color depth. A first color gamut conversion unit that performs gamut conversion and outputs a video signal of a 4K video in 10-bit units operating at 60 Hz,
The third video reproduction section,
For the video signal of 2K video in 12-bit units operating at 120 Hz, which is a vL2-L hierarchical image of 30 Hz distinguished by the packet reception unit, color gamut conversion from RGB 12-bit color depth to RGB 8-bit color depth is performed, and RGB conversion is performed. Video signal reception, including a second color gamut conversion unit that converts the value into a YUV value in YUV 4: 0: 0 format and outputs a video signal of an 8K unit 2K video operating at 30 Hz apparatus. And Film image signal transmitting apparatus, a router and a first video signal receiving apparatus, a composed video signal transmitting and receiving system and a second video signal receiving apparatus,
The video signal transmitting device,
For the first layer, 5-3 conversion is performed in the horizontal direction according to the wavelet 5-3 lossless conversion method based on an image of a predetermined resolution, and a high-pass filter is applied to obtain a horizontal high-pass filter hierarchical image (hH). And a horizontal low-pass filter hierarchical image (hL) is generated by applying the low-pass filter, the 5-3 conversion is performed in the vertical direction based on the horizontal low-pass filter hierarchical image (hL), and a vertical high-pass filter is applied by applying the high-pass filter. A hierarchical image (vH) and a vertical low-pass filter hierarchical image (vL) are generated by applying a low-pass filter,
For the n-th layer (n is an integer of 2 or more), the 5-3 conversion is performed in the horizontal direction based on the vertical low-pass filter layer image (vL) of the (n-1) th layer, and the horizontal high-pass filter is used. A filter hierarchy image (hH) and the horizontal low-pass filter hierarchy image (hL) are generated, and the vertical high-pass filter hierarchy image is subjected to the 5-3 conversion in the vertical direction based on the horizontal low-pass filter hierarchy image (hL). (VH) and the vertical low-pass filter hierarchical image (vL), which is a 5-3 conversion unit,
A distinction for distinguishing each hierarchical image in the horizontal high-pass filter hierarchical image (hH), the vertical high-pass filter hierarchical image (vH), and the vertical low-pass filter hierarchical image (vL) generated by the 5-3 conversion unit. A header addition section for adding information to the header,
A packet transmitting unit that generates a packet of each hierarchical image to which the header is added by the header adding unit and transmits the packet of each hierarchical image as an uncompressed hierarchical video signal,
The packet transmission unit transmits packets of the horizontal high-pass filter layer image (hH) and the vertical high-pass filter layer image (vH) for the first to (n-1) th layers, and the nth layer. About the horizontal high-pass filter layer image (hH), the vertical high-pass filter layer image (vH) and the vertical low-pass filter layer image (vL),
The router is
The packet transmitted from the video signal transmitting device is received, the transmission request is received from the first video signal receiving device, and the packet of the hierarchical image corresponding to the transmission request is received from the first packet, To the video signal receiving device of the second video signal receiving device, the transmission request from the second video signal receiving device is received, and the packet of the hierarchical image corresponding to the transmission request is received from the second video signal receiving device. Send to
The first video signal receiving device,
A first packet request unit for transmitting a transmission request for acquiring the horizontal high-pass filter hierarchical image (hH), the vertical high-pass filter hierarchical image (vH) and the vertical low-pass filter hierarchical image (vL),
A first packet receiving unit that receives a packet corresponding to the transmission request from the router and distinguishes a hierarchical image based on the distinguishing information added to the header of the packet;
Based on the vertical high-pass filter hierarchical image (vH) and the vertical low-pass filter hierarchical image (vL) distinguished by the first packet receiving unit, 5-3 inverse transformation in the vertical direction according to the wavelet 5-3 lossless transformation method And the horizontal low-pass filter hierarchical image (hL) is reproduced, based on the horizontal high-pass filter hierarchical image (hH) distinguished by the first packet receiving unit and the reproduced horizontal low-pass filter hierarchical image (hL). Then, the 5-3 inverse conversion unit which performs the 5-3 inverse conversion in the horizontal direction, reproduces the original image having the predetermined resolution, and outputs the image as a high-resolution video signal,
First data for extracting the vertical low-pass filter hierarchical image (vL) from the hierarchical image distinguished by the first packet receiving unit and outputting the vertical low-pass filter hierarchical image (vL) as a low-resolution video signal. And an extraction unit,
The second video signal receiving device,
A second packet request unit for transmitting a transmission request for acquiring the vertical low-pass filter hierarchical image (vL) to the router;
A second packet receiving unit that receives a packet corresponding to the transmission request from the router and distinguishes the vertical low-pass filter hierarchical image (vL) based on the distinguishing information added to the header of the packet;
A second data extraction unit that extracts the vertical low-pass filter hierarchical image (vL) distinguished by the second packet receiving unit and outputs the vertical low-pass filter hierarchical image (vL) as the low-resolution video signal; A video signal transmission / reception system comprising:

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