JP2018042269A - Reception device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To give notice or warning to a user before the user views a high dynamic range video that broadcasts the existence of a blinking portion that has remarkable blinking.SOLUTION: An accompanying information processing part acquires brightness information about blinking of a high dynamic range video having brightness of a range wider than a broadcasted standard on the basis of accompanying information accompanied to the high dynamic range video, a notification information processing part outputs notification information showing the existence of a blinking portion on the basis of the brightness information when the high dynamic range video is determined to include a blinking portion having a blinking degree that is more remarkable than a prescribed blinking degree, the brightness information includes at least one between a frequency in which a representative value of the brightness per prescribed unit time in the high dynamic range video changes between frames by a prescribed amount or more and difference between the frames of the representative value of the brightness per unit time, and the notification information processing part determines that a blinking portion is included when the brightness information is larger than a prescribed frequency or larger than prescribed difference.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a receiving apparatus.

  As part of the advancement of television broadcasting, there is HDR (High Dynamic Range; also called high dynamic range, high dynamic range, wideband dynamic range) video. The HDR video is displayed with higher brightness than before, and the video quality is improved. On the other hand, it is known that when the user visually recognizes a scene in which the luminance of the video is rapidly repeated in a short time, the user's physical condition is deteriorated.

In Patent Document 1, the luminance blinking repetition frequency of a portion in which a significant change in luminance repeatedly appears in the displayed video signal and the maximum luminance of the luminance blinking portion are detected, and the luminance blinking repetition frequency is a predetermined frequency. There is described a luminance suppression device that suppresses and displays the luminance of a video signal when it is determined by a control device that it is in a frequency range and the maximum luminance exceeds a predetermined luminance level.
Patent Document 2 describes a display device that causes a light emitting unit to emit light when there is a scene in which an amount of change in luminance per predetermined time is larger than a predetermined value in an image.

JP-A-11-234583 JP 2014-64229 A

  Since the maximum brightness of an HDR video is higher than the maximum brightness of an image having a normal brightness range (SDR: Standard Dynamic Range), the amount of change in the brightness in a scene where the brightness of the video repeats abrupt changes in a short time. Also grows. As a result, the risk of physical health is further increased. There has been a need to notify or warn the user of the possibility at the start of viewing the program or before the scene.

  The present invention has been made to solve the above-described problems, and one aspect of the present invention provides luminance information relating to blinking of a high dynamic range image having a wider range of luminance than a broadcast standard. When determining that the accompanying information processing unit that is acquired based on the accompanying information attached to the video, and based on the luminance information, the high dynamic range video includes a blinking part that has a blinking level that is significantly higher than a predetermined blinking level. A notification information processing unit that outputs notification information indicating the presence of the blinking part, and the luminance information includes a representative value of the luminance per predetermined unit time in the high dynamic range video that is a predetermined amount or more between frames. Including at least one of the number of times of change and the difference between frames of the representative value of the luminance per unit time, the notification information processing unit When the number of times is larger than the predetermined number of times, or when the difference is larger than the predetermined difference, it is determined that the blinking part is included, and a setting menu screen is displayed on the display unit, and the predetermined number of times or It is a receiving device that sets the predetermined difference.

  According to the embodiment of the present invention, a user can be notified or warned before watching a high dynamic range video broadcast of the presence of a blinking part that is blinking significantly.

It is a schematic block diagram which shows the structure of the broadcast system which concerns on 1st Embodiment. It is a schematic block diagram which shows the structure of the transmitter which concerns on 1st Embodiment. It is a schematic block diagram which shows the structure of the receiver which concerns on 1st Embodiment. It is a figure which shows an example of the data structure of MPT which concerns on 1st Embodiment. It is a figure which shows an example of the blink information which concerns on 1st Embodiment. It is a figure which shows an example of the brightness change information which concerns on 1st Embodiment. It is a figure which shows an example of the maximum luminance information which concerns on 1st Embodiment. It is a figure which shows an example of the process based on the luminance information which concerns on 1st Embodiment. It is a figure which shows the other example of the process based on the luminance information which concerns on 1st Embodiment. It is a figure which shows the further another example of the process based on the luminance information which concerns on 1st Embodiment. It is a figure which shows an example of a data structure of the accompanying information which concerns on the modification of 1st Embodiment. It is a figure which shows an example of the data area in which the brightness | luminance information which concerns on the modification of 1st Embodiment is stored. It is a figure which shows an example of the data area in which the blink information which concerns on the modification of 1st Embodiment is stored. It is a figure which shows an example of the data area in which the representative brightness | luminance information which concerns on the modification of 1st Embodiment is stored. It is a schematic block diagram which shows the structure of the broadcast system which concerns on 2nd Embodiment. It is a schematic block diagram which shows the structure of the receiver which concerns on 2nd Embodiment. It is a figure which shows the example of the application control which concerns on 2nd Embodiment. It is a figure which shows one execution example of the application which concerns on 2nd Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
First, an overview of the broadcast system 1 according to the first embodiment of the present invention will be described.
FIG. 1 is a schematic block diagram showing a configuration of a broadcasting system 1 according to the present embodiment.
The broadcast system 1 includes a transmission device 10 and a reception device 20.
The transmission device 10 transmits program data representing the content of the broadcast program to the reception device via the broadcast transmission path BT. The content includes video and audio. In the following description, the content may mean a program or a video provided by the program. The broadcast transmission path BT is a transmission path for unilaterally and simultaneously transmitting program data to an unspecified number of receiving devices 20. The broadcast transmission path BT is a broadcast wave having a predetermined frequency band, for example. The broadcast transmission path BT may include a broadcast satellite BS that relays broadcast waves. A part of the broadcast transmission path BT may include a network, for example, a dedicated line or a VPN (Virtual Private Network). The receiving device 20 receives program data transmitted via the broadcast transmission path BT. The receiving device 20 displays an image based on the received program data. The receiving device 20 is an electronic device such as a television receiving device or a set-top box that can receive program data and display a video related to the received program data on a display unit. Although the number of transmitting apparatuses 10 and receiving apparatuses 20 shown in FIG. 1 is one each, there are generally a plurality. Further, a case where the broadcasting system 1 uses an MMT (MPEG Media Transport) system as a media transport system is taken as an example.

  The broadcast system 1 can broadcast programs having different luminance dynamic ranges. In other words, in the broadcast system 1, an HDR broadcast program and an SDR broadcast program are broadcast. The HDR broadcast program is a program including an HDR video whose luminance range is HDR. The SDR broadcast program is a program including an SDR video whose luminance range is SDR. Video data representing HDR video and video data representing SDR video are referred to as HDR video data and SDR video data, respectively.

(Brightness of image)
There are two types of video brightness, optical brightness and image brightness. Optical luminance is one of physical quantities representing the brightness of a light source. The optical luminance is used, for example, to represent the brightness of an image emitted from the display. In the present embodiment, as an example, referred to as HDR luminance range 0~10000cd / ^{m 2,} referred to the luminance range of 0~100cd / ^{m 2} and SDR. That is, HDR has a wider dynamic range of optical brightness than SDR. Note that the HDR and SDR luminance ranges are not limited to those described above, and may be arbitrarily determined according to, for example, a broadcasting system. Hereinafter, the dynamic range of the optical brightness may be simply referred to as the dynamic range. The image brightness means a signal level representing the brightness of an image or a relative value thereof. In the following description, optical luminance and image luminance may be referred to as luminance and luminance value, respectively.

The broadcast system 1 transmits program data including HDR video data or SDR video data. The HDR video data is, for example, SMPTE (Society of Motion Picture and Television Engineers) ST. 2084-2014, CTA (Consumer Technology Association) -861-F, ARIB (Association of Radio Industries and Businesses) STD-B67. In the following description, the data format of the HDR video data is referred to as the HDR format. In the HDR video data, the luminance within the HDR luminance range is associated with the luminance value. When the luminance value for each pixel is represented by 10 bits, for example, the luminance value of 64 to 940 corresponds to the luminance of 0 to 10000 cd / m ² .

The SDR video data is, for example, Rec. ITU-R BT. 709. In the following description, the data format of SDR video data is referred to as the SDR format. In the SDR video data, the luminance within the luminance range of SDR is associated with the luminance value. In SDR video data, the number of bits for representing the luminance value for each pixel is smaller than that in HDR video data. For example, when the luminance value for each pixel is represented by 8 bits, the luminance value of 16 to 240 corresponds to the luminance of 0 to 100 cd / m ² . The minimum value (for example, 64 when represented by 10 bits) and the maximum value (for example, 940 when represented by 10 bits) are also referred to as a reference black level and a reference white level.

(Configuration of transmitter)
Next, the configuration of the transmission device 10 according to the present embodiment will be described.
FIG. 2 is a schematic block diagram illustrating a configuration of the transmission device 10 according to the present embodiment.
The transmission device 10 transmits multiplexed data obtained by multiplexing program data and accompanying information accompanying the program data to the broadcast transmission path BT. The transmission apparatus 10 includes an accompanying information acquisition unit 110, a video encoding unit 120, an audio encoding unit 130, a multiplexing unit 140, an error correction encoding unit 150, a modulation unit 160, and a transmission unit 170.

  The accompanying information acquisition unit 110 acquires accompanying information accompanying program data. The accompanying information may include the type of program component. When the component is a video, the accompanying information can include the luminance range of the video and the luminance information regarding the blinking of the luminance. The accompanying information acquisition unit 110 may generate the luminance information by analyzing the video indicated by the video data input from another device, or may input the luminance information corresponding to the video data. When the MMT (MPEG Media Transport) method is used as a multiplexed transmission method of program data, for example, MMT-SI (Service Information) is used as a data format of accompanying information. The luminance information is described in MPT (MMT Package Table; MMT package table) which is a component of MMT-SI. When the video data is an HDR signal defined by CTA-861-F, the luminance information may be described in an information frame (InfoFrame). The luminance information includes a flash scene flag (flash_scene) as information indicating the presence / absence of a blinking portion where the luminance blinking is more significant than a predetermined blinking level, and a flash scene level (flash_scene_level) as information indicating the luminance blinking level. An example of the luminance information will be described later. The accompanying information acquisition unit 110 outputs the acquired accompanying information to the multiplexing unit 140.

  The video encoding unit 120 encodes video data input from another device using a predetermined encoding method (for example, ISO / IEC 23008-2 HEVC: High Efficiency Video Coding). The video encoding unit 120 generates video data including encoded data obtained by encoding. The video encoding unit 120 outputs the generated video data to the multiplexing unit 140.

  The audio encoding unit 130 encodes input audio data using a predetermined encoding method (for example, ISO / IEC 14496-3 MPEG-4 AUDIO). The audio encoding unit 130 outputs audio data including audio encoded data obtained by encoding to the multiplexing unit 140.

  The multiplexing unit 140 multiplexes the accompanying information input from the accompanying information acquisition unit 110, the video data input from the video encoding unit 120, and the audio data input from the audio encoding unit 130 to obtain a predetermined format ( For example, multiplexed data having MMT format) is generated. Multiplexer 140 outputs the generated multiplexed data to error correction encoder 150. Note that either or both of video data and audio data may be input to the multiplexing unit 140 from another device. If the format of the video data from another device is the same as the format of the video data from the video encoding unit 120, the video encoding unit 120 may be omitted. If the format of the audio data from the other device is the same as the format of the audio data from the audio encoding unit 130, the audio encoding unit 130 may be omitted.

  The error correction coding unit 150 performs error correction coding on the multiplexed data input from the multiplexing unit 140 using a predetermined error correction coding method, and performs a predetermined error correction code (for example, LDPC: low-density parity). -Check code). The error correction coding unit 150 outputs multiplexed data to which the error correction code obtained by error correction coding is added to the modulation unit 160.

The modulation unit 160 modulates the multiplexed data input from the error correction coding unit 150 using a predetermined modulation method (for example, 16-value amplitude phase modulation method (16APSK: 16-ary amplitude and phase-shift keying)). To do. Modulation section 160 outputs modulation data obtained by the modulation to transmission section 170.
The transmission unit 170 modulates the modulation data of the base frequency band input from the modulation unit 160 to generate a broadcast signal having a predetermined frequency band. The transmission unit 170 transmits the generated broadcast signal to the broadcast transmission path BT. The broadcast signal is transmitted as a broadcast wave. Therefore, a broadcast signal carrying multiplexed data obtained by multiplexing program data and accompanying information is transmitted via the broadcast transmission path BT. The transmission unit 170 includes, for example, a transmitter.

(Receiver configuration)
Next, the configuration of the receiving device 20 according to this embodiment will be described.
FIG. 3 is a schematic block diagram illustrating a configuration of the receiving device 20 according to the present embodiment.
The receiving device 20 includes a broadcast receiving unit 210, a demodulating unit 211, an error correcting unit 212, a separating unit 213, an input unit 215, a video decoding unit 221, a video processing unit 222, a display control unit 223, an audio decoding unit 231, and an audio processing unit. 232, an amplifier 233, a control unit 240, a storage unit 250, a display unit 22, and a loudspeaker unit 23. One or both of the display unit 22 and the loudspeaker unit 23 may be detachable from the main body of the receiving device 20.

  The broadcast receiving unit 210 receives a channel selection signal from a channel selection unit 241 (described later) of the control unit 240. The broadcast receiving unit 210 receives a broadcast signal transmitted through a channel indicated by the channel selection signal. The broadcast receiving unit 210 includes a tuner that receives broadcast waves. The tuner receives a broadcast wave in a frequency band corresponding to the channel specified by the channel selection signal. The broadcast receiving unit 210 down-converts the received broadcast signal to generate modulation data in the base frequency band, and outputs the generated modulation data to the demodulation unit 211.

  The demodulator 211 demodulates the modulation data input from the broadcast receiver 210 using a predetermined demodulation method. The predetermined modulation method is a demodulation method corresponding to the modulation method used by the modulation unit 160. Demodulation section 211 outputs multiplexed data to which the error correction code obtained by decoding is added to error correction section 212.

  The error correction unit 212 separates the error correction code from the multiplexed data input from the demodulation unit 211. The error correction unit 212 performs error correction on the multiplexed data using the separated error correction code. The error correction unit 212 outputs multiplexed data obtained by performing error correction to the separation unit 213.

  The separation unit 213 separates program data and accompanying information from the multiplexed data input from the error correction unit 212. The separation unit 213 separates video data and audio data from the separated program data. The separation unit 213 outputs the separated video data to the video decoding unit 221, and outputs the separated audio data to the audio decoding unit 231. The separation unit 213 outputs the separated accompanying information to the accompanying information processing unit 242 of the control unit 240.

  The input unit 215 receives an operation signal generated by a user operation. The input unit 215 includes, for example, an infrared interface that receives an operation signal from a remote controller (control device) RC using infrared rays. For example, the operation signal specifies information such as power on / off, a channel for receiving a broadcast wave, luminance, and luminance range. The input unit 215 outputs an operation signal to the control unit 240. Note that the input unit 215 may include a physical member for receiving a user operation, for example, various buttons and knobs, and may generate an operation signal corresponding to the operation. The input unit 215 outputs the input operation signal to the control unit 240.

  Video data is input from the separation unit 213 to the video decoding unit 221. The video decoding unit 221 decodes the input video data using a predetermined video decoding method. The predetermined video decoding method is a decoding method corresponding to the encoding method used by the video encoding unit 120. The video decoding unit 221 outputs the decoded video data to the video processing unit 222.

  The video processing unit 222 performs predetermined processing on the video data input from the video decoding unit 221. For example, when notification screen data is input as notification information from the notification information processing unit 243 of the control unit 240, the video processing unit 222 superimposes the notification screen indicated by the notification screen data on the video indicated by the video data. The notification screen is a screen that indicates the presence of a blinking portion having a blinking level that is significantly higher than a predetermined blinking rate in the HDR video provided in the program. In addition, when the input video data is HDR video data, the video processing unit 222 adjusts the luminance of the HDR video indicated by the HDR video data to a luminance within a narrower luminance range. The narrow luminance range is, for example, within a predetermined luminance range of the SDR video. The video processing unit 222 adjusts the brightness in response to the input of the operation signal from the input unit 215, and may not be performed when the operation signal is not input. Further, the video processing unit 222 can determine whether the luminance range of the video is HDR or SDR based on the luminance information input from the accompanying information processing unit 242. The video processing unit 222 outputs video data indicating the video obtained by the processing to the display control unit 223. When the process is not performed, the video processing unit 222 outputs the video data input from the video decoding unit 221 to the display control unit 223. An example of processing based on luminance information will be described later.

  The display control unit 223 controls the luminance of the video indicated by the video data input from the video processing unit 222 based on the control parameter indicated by the operation signal input from the input unit 215 via the control unit 240. The control parameter includes, for example, a gain and an offset value. The gain and offset values are parameters for adjusting the contrast and brightness of the video by multiplying and adding to the luminance value, respectively. The display control unit 223 outputs to the display unit 22 video data indicating a display video whose luminance is controlled.

  The display unit 22 displays a video based on the video data input from the display control unit 223. The display unit 22 is, for example, a liquid crystal display (LCD: Liquid Crystal Display), an organic EL (Electroluminescence) display, or the like. As the display unit 22, a display capable of displaying the luminance within the luminance range of the HDR video is used.

Audio data is input from the separation unit 213 to the audio decoding unit 231. The voice decoding unit 231 decodes the input voice data using a predetermined voice decoding method. The predetermined speech decoding method is a decoding method corresponding to the encoding method used by the speech encoding unit 130. The audio decoding unit 231 outputs the decoded audio data to the audio processing unit 232.
The voice processing unit 232 performs predetermined processing on the voice data input from the voice decoding unit 231. For example, the voice processing unit 232 mixes the voice indicated by the voice data input from the control unit 240 with the voice indicated by the voice data input from the voice decoding unit 231 as the predetermined process. The audio processing unit 232 outputs audio data indicating the audio obtained by the processing to the amplifier 233.
The amplifier 233 controls the sound volume indicated by the sound data input from the sound processing unit 232 based on the control parameter indicated by the operation signal input from the input unit 215 via the control unit 240. The control parameter includes, for example, a gain value. The gain value is a parameter for adjusting the volume by multiplying the audio signal value. The amplifier 233 outputs sound data indicating the sound for reproduction whose volume is controlled to the loudspeaker 23.

  The loudspeaker 23 reproduces sound based on the sound data input from the amplifier 233. The loudspeaker 23 includes, for example, a speaker.

The control unit 240 performs various controls related to the operation of the receiving device 20. The control unit 240 includes a channel selection unit 241, an accompanying information processing unit 242, and a notification information processing unit 243.
The channel selection unit 241 identifies a channel that receives a broadcast signal from the operation signal input from the input unit 215. The channel selection unit 241 generates a channel selection signal indicating the identified channel, and outputs the generated channel selection signal to the broadcast reception unit 210.

  The accompanying information processing unit 242 performs various controls related to the presentation of the program based on the accompanying information input from the separating unit 213. The accompanying information processing unit 242 extracts luminance information of the video that is a component of the program from the accompanying information. The accompanying information processing unit 242 outputs the extracted luminance information to the video processing unit 222 and the notification information processing unit 243.

  The notification information processing unit 243 includes, based on the luminance information input from the accompanying information processing unit 242, the video to be broadcast is an HDR video, and the video includes a blinking portion having a blinking rate that is significantly higher than a predetermined blinking level. It is determined whether or not. When determining that the blinking portion is included, the notification information processing unit 243 reads the notification screen data stored in advance in the storage unit 250 and outputs the read notification screen data to the video processing unit 222 as notification information.

  The storage unit 250 stores various data such as setting data used by the control unit 240 and data acquired by the control unit 240. The storage unit 250 includes various storage media such as a RAM (Random Access Memory) and a ROM (Read-only Memory).

(Summary of luminance information)
Next, an example of luminance information included in the accompanying information will be described. The luminance information is roughly divided into the following three types of information (1) to (3). In the present embodiment, at least one of the information (1) to (3) may be included.
(1) Information (blinking information) indicating whether or not the blinking degree of luminance includes a blinking section that is a section that is more marked than the predetermined blinking degree, (2) Change in luminance per unit time (for example, 3 to 10 seconds) (3) A representative value of luminance (representative luminance information). The representative value of the brightness is a representative value in a certain section, for example, the maximum value or the average value of the brightness in the whole or a part of the program.

(MPT)
When the program data is transmitted using the MMT system as the transmission / multiplexing system, the luminance information is described in the MPT descriptor area as an example.
FIG. 4 is a diagram illustrating an example of the data structure of the MPT according to the present embodiment.
In the example shown in FIG. 4, MPT (MMT_Package_Table ()) stores configuration information indicating the configuration of program data. The MPT includes a version, an MPT descriptor area (MPT_descriptors_byte), and an asset type (asset_type) for each asset. The MPT descriptor area is an MPT descriptor. In the MPT descriptor, luminance information is described as a descriptor relating to program data transmitted at that time. Therefore, the accompanying information processing unit 242 of the receiving device 20 extracts luminance information from the MPT included in the accompanying information. The luminance information is set for each program, for example. The version indicates an MPT version number. Each time the information stored in the MPT is updated, the version number is updated in ascending order. When the luminance information is updated in accordance with the switching of programs as time passes, a value obtained by adding a predetermined increment value (for example, 1) to the version number at that time is updated as a new version number. .

  The asset type (asset_type) is information indicating the type of asset. An asset means a component of a program. For example, an asset in which “hvc1” is described as the asset type indicates video, and an asset in which “mp4a” is described as the asset type indicates audio. Note that the luminance information may be described in an asset descriptor area (asset_descriptors_byte) related to the asset of the broadcast video. Thereby, the accompanying information processing unit 242 can immediately determine a video to be processed using the luminance information. Note that an HDR flag indicating whether the video is an HDR video or an SDR video may be included as part of the luminance information. Thereby, the accompanying information processing unit 242 can determine whether or not the video is an HDR video.

  Next, a specific example of luminance information will be described. FIG. 5 is a diagram showing an example of (1) blinking information as one type of luminance information according to the present embodiment. In the example illustrated in FIG. 5, the blinking information includes a flash scene flag (flash_scene) and a flash scene level (flash_scene level). The flash scene flag indicates a value of 1 when the video provided in the program has a flash scene, and indicates a value of 0 when the video does not have a flash scene. The flash scene means a blinking section, which is a section (scene) of a video in which the blinking degree of the video is more remarkable than a predetermined blinking degree. The flash scene level is a value obtained by discretizing an index value indicating the degree of the flash scene, that is, the blinking level into a predetermined number of steps. In the example shown in FIG. 5, the flash scene level is represented by five levels of integer values from 1 to 5. The larger the flash scene level value, the higher the blinking level. If the value of the flash scene flag is 0, the flash scene level may not be set. The accompanying information acquisition unit 110 of the transmission device 10 calculates a blinking index value for each unit time for the video indicated by the input video data. The blinking index value is, for example, any one of a maximum brightness change count, a maximum brightness change amount, an average brightness change count, and an average brightness change amount, or a plurality or all of the values described later. The sum of multiplication values obtained by multiplying a predetermined weight coefficient may be used.

  When generating luminance information, the incidental information acquisition unit 110 determines a section where the index value calculated every unit time (for example, 3 to 10 seconds) is larger than a predetermined index value as a flash scene, and the other sections Is determined as a non-flash scene. The accompanying information acquisition unit 110 sets the value of the flash scene flag to 1 when there is a section determined as a flash scene for the video provided in the program. The accompanying information acquisition unit 110 determines the value of the flash scene flag as 0 when there is no section determined as a flash scene for the video provided in the program. Further, the accompanying information acquisition unit 110 discretizes the index value in the section determined as the flash scene into a predetermined number of steps, and calculates the flash scene level value.

  FIG. 6 is a diagram showing an example of (2) luminance change information as another type of luminance information according to the present embodiment. In the example illustrated in FIG. 6, the luminance change information includes the maximum luminance change count, the maximum luminance change amount, the average luminance change count, and the average luminance change amount. The accompanying information acquisition unit 110 of the transmission device 10 calculates the maximum brightness change count, the maximum brightness change amount, the average brightness change count, and the average brightness change amount as index values per unit time for the video indicated by the input video data. The brightness change information is generated using the calculated index value.

  The maximum number of luminance changes shown in the second row of FIG. 6 is the maximum value in the program of the maximum number of luminance changes per unit time of video provided in the program. The maximum luminance change count per unit time is the number of times that the inter-frame change amount of the maximum luminance, which is a representative value of the luminance for each frame within the unit time, is equal to or greater than a predetermined change amount. The interframe change amount is an absolute value of a difference between adjacent frames. As the predetermined amount of change, for example, a threshold value of the amount of change in luminance that may affect the physical condition of the viewer when the change in luminance is repeated may be used. More specifically, the predetermined change amount may be set based on a predetermined ratio with respect to the luminance range of the HDR video signal. The luminance range is represented by the maximum luminance value and the minimum luminance value. The ratio to the luminance range is, for example, about 20% to 30%. Since the change in the maximum luminance between frames directly represents the blinking of the video, the accompanying information acquisition unit 110 counts the number of blinks in which the change in the maximum luminance exceeds a predetermined change amount as the maximum number of luminance changes. When the predetermined ratio is 20% and the luminance value is represented by 10 bits, the predetermined change amount is (maximum luminance value (for example, 940) −minimum luminance value (for example, 64)) · 20, that is, 175. In this case, the accompanying information acquisition unit 110 counts the number of times that the change amount of the maximum luminance between frames is larger than 175 in the video provided by the program as the maximum luminance change number.

The maximum luminance change amount shown in the third row of FIG. 6 is the maximum value in the program of the maximum luminance change amount per unit time of the video provided in the program. The maximum luminance change amount per unit time is the maximum value among the inter-frame change amounts of the maximum luminance, which is a representative value of the luminance for each frame within the unit time.
The average luminance change amount shown in the fourth line of FIG. 6 is the maximum value in the program of the average luminance change count per unit time of the video provided in the program. The average luminance change count per unit time is the number of times that the inter-frame change amount of the average luminance, which is a representative value of the luminance for each frame within the unit time, is equal to or greater than a predetermined change amount. As described above, the predetermined change amount may be set based on a predetermined ratio with respect to the luminance range of the HDR video signal. However, since the average luminance is the average of the luminance of the entire frame, the time change is more gradual than the maximum luminance. Therefore, a value smaller than the predetermined change amount used for counting the maximum luminance change number is set as the predetermined change amount used for counting the average luminance change number. The predetermined change amount used for counting the average luminance change count may be, for example, about ¼ of the predetermined change amount used for counting the maximum luminance change count. In that case, the ratio to the luminance range is 5.0 to 7.5%.
The average luminance change amount shown in the fifth line of FIG. 6 is the maximum value in the program of the average luminance change amount per unit time of the video provided in the program. The average luminance change amount per unit time is the maximum value among the inter-frame change amounts of the average luminance, which is a representative value of the luminance for each frame within the unit time.
In the present embodiment, the brightness change information may not include all index values of the maximum brightness change count, the maximum brightness change amount, the average brightness change count, and the average brightness change amount, and at least the index values thereof. One of them may be included. Further, an average value may be used as a representative value in the content instead of the maximum value.

  FIG. 7 is a diagram showing an example of (3) representative luminance information as yet another type of luminance information according to the present embodiment. The example shown in FIG. 7 includes a maximum content luminance level (MaxCLL: Maximum Content Light Level) and a maximum frame average luminance level (MaxFALL: Maximum Frame-Average Light Level) defined by CTA-861-F.

  The accompanying information acquisition unit 110 of the transmission device 10 acquires the maximum content luminance level and the maximum frame average luminance level as index values for a series of scenes of the video indicated by the input video data, and uses the acquired index values to determine the luminance. Generate change information. The series of scenes may be the entire program or each section that is a part of the program. The section may be a section divided every predetermined unit time, or may be a section arbitrarily set by the producer.

The maximum content luminance level is the maximum value of the luminance level of the video in a series of scenes. The maximum frame average luminance level is the maximum value of the frame average luminance level of a series of scenes. The frame average luminance level is an average value of luminance levels for each frame. The luminance level may be a value expressed as physical luminance, or may be a luminance value converted from the physical luminance using a predetermined OETF (Opto-electric Transfer Function, photoelectric conversion function).
In the present embodiment, the representative luminance information may not include the index values of both the maximum content luminance level and the maximum frame average luminance level, and may include at least one of those index values. That's fine. Further, instead of or together with the maximum content luminance level or the maximum frame average luminance level, an average content luminance level or an average frame average luminance level may be included.

(Example of processing)
Next, an example of the processing performed by the video processing unit 222 and the processing performed by the notification information processing unit 243 will be described by taking as an example the case where the luminance information changes as the program is switched. FIG. 8 is a diagram illustrating an example of processing based on luminance information according to the present embodiment.
In the example shown in FIG. 8, the luminance information includes a flash scene flag (flash_scene) and a flash scene level (flash_scene level).
The broadcast content is all HDR video, and is sequentially switched to content P, content A, and content B as time passes. The value of the fresh scene flag and the value of the flash scene level relating to the contents P and B are both 0. The value of the flash scene flag and the value of the flash scene level related to the content A are 1 and 3, respectively. The flash scene level value set as the index value of the predetermined blinking level is 2. The index value of the predetermined blinking level can be arbitrarily set by the user via the setting menu. In the setting, when the setting menu screen is displayed on the display unit 22, the control unit 240 determines a value indicated by the operation signal input from the input unit 215 as an index value of a predetermined blinking level and stores it in the storage unit 250. Setting information including the value is stored in the storage unit 250.

  When the content to be broadcast is switched from content P to content A, the notification information processing unit 243 detects that the value of the flash scene flag included in the luminance information changes from 0 to 1. The notification information processing unit 243 compares the flash scene level value included in the luminance information with a preset flash scene level value. Since the value of the flash scene level included in the luminance information is larger, the notification information processing unit 243 determines that the flash scene whose flash scene level is higher than the set flash scene level is included in the video of the content A. The notification information processing unit 243 reads the notification screen data from the storage unit 250 and outputs the read notification screen data to the video processing unit 222. The video processing unit 222 causes the display unit 22 to display a notification screen including a predetermined message from when the content A is switched.

  The message to be displayed includes, for example, a sentence “This content includes a scene with high blinking” indicating that the degree of blinking is remarkable. The message to be displayed may include a message “Do you want to watch?” Prompting the user to determine whether or not to watch. Further, the message to be displayed may include a message “Do you want to switch from HDR to SDR?” Or “Do you want to reduce the maximum brightness?” Prompting the user to determine whether or not to reduce the brightness range. . Before viewing the content A video, the user is warned or notified that the video of content A includes a blinking section with a significant blinking level. In addition, at the time of content switching or the like, the luminance data included in the accompanying information may be detected before the video data received is decoded. In that case, the notification information processing unit 243 can display the notification screen on the display unit 22 before the video of the content after switching is displayed. Therefore, the user is warned or notified that a blinking section having a significant blinking degree is included before viewing the content. The warning or notification prompts the user to stop viewing the video, or to reduce the luminance of the video by an operation, or to reduce the luminance range of the video from HDR to SDR.

On the other hand, the video processing unit 222 may detect that the video of the content A is an HDR video based on the luminance information, and narrow the luminance range of the video of the content A. As a narrower luminance range, the video processing unit 222 may determine the luminance range of the SDR or reduce the maximum luminance of the video. Therefore, the user can continue to view the video with the reduced blinking level without performing an operation after recognizing that the blinking section is included in the video.
When lowering the maximum luminance, the video processing unit 222 may determine the maximum luminance of the content A as the maximum luminance of the SDR video, or the luminance obtained by multiplying the original maximum luminance by a predetermined attenuation factor. You may decide to. The video processing unit 222 performs, for example, clipping processing, attenuation (compression processing), and luminance of a light emitting unit (for example, a backlight) included in the display unit 22 via the display control unit 223 as processing for reducing the maximum luminance. Any method such as reduction may be used.

When the content to be broadcast is switched from content A to content B, the notification information processing unit 243 detects that the value of the flash scene flag included in the luminance information changes from 1 to 0. At this time, the notification information processing unit 243 determines that the video of the content B does not include a flash scene. Therefore, the notification information processing unit 243 erases the displayed notification screen without displaying the notification screen on the display unit 22. The video processing unit 222 determines the luminance range of the content B video as a predetermined luminance range for the HDR video. Therefore, the notification information processing unit 243 stops the process of narrowing the luminance range for the broadcast content video.
Even when the flash scene flag value is maintained at 1 as the content is switched, the flash scene level value may be equal to or lower than the preset flash scene level value. In that case, the notification information processing unit 243 does not perform processing for displaying the notification screen on the display unit 22.

FIG. 9 is a diagram illustrating another example of processing based on luminance information according to the present embodiment. In the example illustrated in FIG. 9, the luminance information includes the maximum luminance change count and the maximum luminance change amount.
The maximum number of luminance changes related to the contents P, A, and B are 2, 10, and 3, respectively. The maximum luminance change amounts related to the contents P, A, and B are 10, 80, and 10, respectively. The upper limit value of the maximum luminance change number and the upper limit value of the maximum luminance change amount set in advance as index values of the predetermined blinking degree are 5 and 60, respectively.

When the broadcast content is switched from the content P to the content A, the notification information processing unit 243 changes the value of the maximum luminance change number included in the luminance information from 2 to 10 and the value of the maximum luminance change amount from 10 to 80. Detect what to do. The notification information processing unit 243 has a maximum brightness change in which the maximum brightness change count included in the brightness information is larger than a preset upper limit value of the maximum brightness change count and the maximum brightness change amount included in the brightness information is preset. It is determined that the amount is larger than the upper limit value. Based on this determination, the notification information processing unit 243 determines that the video of the content A includes a scene in which the short-time luminance change state is more significant than the predetermined luminance change state.
The notification information processing unit 243 reads the notification screen data from the storage unit 250 and outputs the read notification screen data to the video processing unit 222. The video processing unit 222 causes the display unit 22 to display a notification screen including a predetermined message for a predetermined period from when the content A is switched. As a result, the user is warned or notified that the content A video includes a blinking section with a significant blinking level before viewing the content A video.

  In the present embodiment, the index value indicating the blinking level, such as the upper limit value of the maximum luminance change number and the upper limit value of the maximum luminance change amount, can be arbitrarily set by the user in advance through the setting menu on the menu screen. Also good. Thereby, the user can know in more detail the blinking degree to be warned or notified, and can change the blinking degree according to the degree of the user's light sensitivity. Similarly to the example illustrated in FIG. 8, the video processing unit 222 may detect that the content A video is an HDR video based on the luminance information, and may narrow the luminance range of the content A video. .

  When the content to be broadcast is switched from content A to content B, the notification information processing unit 243 changes the value of the maximum luminance change count included in the luminance information from 10 to 3, and the value of the maximum luminance change amount is 80. Detecting a change from 10 to 10. At this time, the notification information processing unit 243 determines that the scene of the content B does not include a scene whose brightness change state for a short time is more significant than the predetermined brightness change state. Therefore, the notification information processing unit 243 erases the displayed notification screen without displaying the notification screen on the display unit 22. The video processing unit 222 returns the luminance range of the content B video to a predetermined luminance range for the HDR video.

  Note that when the luminance information includes a plurality of types of index values, the notification information processing unit 243 has at least one type of index value that exceeds a preset upper limit value of the index value, and other types of index values. May not exceed the preset upper limit value of the index value. In the example shown in FIG. 9, this corresponds to a case where one of the maximum luminance change count and the maximum luminance change amount exceeds the upper limit value of one of the luminance information. In that case, the notification information processing unit 243 may perform processing for causing the display unit 22 to display a notification screen, or the video processing unit 222 may perform processing for narrowing the luminance range of the content video to be broadcast. Also good. Since a warning or notification or a luminance range is reduced based on at least one of a plurality of types of index values representing the blinking degree of the video, it is possible to reduce a risk of affecting the physical condition of the user by viewing.

FIG. 10 is a diagram showing still another example of processing based on luminance information according to the present embodiment. In the example illustrated in FIG. 10, the luminance information includes a maximum luminance change count and a maximum luminance change amount. The maximum content luminance level (MaxCLL) and the maximum frame average luminance level (MaxFALL) are included.
The maximum content luminance levels related to the contents P, A, and B are 200, 600, and 180, respectively. The maximum frame average luminance levels relating to the contents P, A, and B are 40, 200, and 30, respectively. The upper limit value of the maximum content luminance level and the upper limit value of the maximum frame average luminance level set in advance as index values for the predetermined blinking level are 300 and 50, respectively.

  When the broadcast content is switched from the content P to the content A, the notification information processing unit 243 changes the maximum content luminance level value included in the luminance information from 200 to 600 and the maximum frame average luminance level value from 40 to 200. Detect changes. The notification information processing unit 243 has a maximum content brightness level value included in the brightness information larger than a preset upper limit value of the maximum content brightness level, and a maximum frame average brightness level included in the brightness information is preset. It is determined that the maximum frame average luminance level is larger than the upper limit value. In moving images, it is customary that the brightness of the image changes from moment to moment. Therefore, based on this determination, the notification information processing unit 243 determines that the scene of the content A includes a scene whose blinking degree is more significant than the predetermined blinking degree. The notification information processing unit 243 reads the notification screen data from the storage unit 250 and outputs the read notification screen data to the video processing unit 222. The video processing unit 222 causes the display unit 22 to display a notification screen including a predetermined message for a predetermined period from when the content A is switched. As a result, the user is warned or notified that the content A video includes a blinking section with a significant blinking level before viewing the content A video.

  In addition, index values indicating blinking levels such as the upper limit value of the maximum content luminance level and the upper limit value of the maximum frame average luminance level may be arbitrarily set by the user in advance via a setting menu on the menu screen. 8 and 9, the video processing unit 222 detects that the video of the content A is an HDR video based on the luminance information, and narrows the luminance range of the video of the content A. Also good.

  When the content to be broadcast is switched from content A to content B, the notification information processing unit 243 changes the value of the maximum content luminance level included in the luminance information from 600 to 180 and the value of the maximum frame average luminance level. A change from 200 to 30 is detected. At this time, the notification information processing unit 243 determines that a scene whose blinking degree is more remarkable than the predetermined blinking degree is not included in the video of the content B. Therefore, the notification information processing unit 243 erases the displayed notification screen without displaying the notification screen on the display unit 22. The video processing unit 222 returns the luminance range of the content B video to a predetermined luminance range for the HDR video. When one of the maximum content luminance level value and the maximum frame average luminance level exceeds the upper limit value of one of the luminance information, the notification information processing unit 243 performs a process for causing the display unit 22 to display the notification screen. Alternatively, the video processing unit 222 may perform processing for narrowing the luminance range for the content video to be broadcast.

  In the examples shown in FIGS. 8 to 10, it is assumed that the luminance information changes with the switching of the content as time elapses when the channel for receiving the broadcast signal is maintained unchanged without being changed. did. The illustrated processing may be applied to changes in luminance information in response to channel switching in addition to changes in luminance information in accordance with the passage of time. In addition, the video processing unit 222 sets a predetermined period for displaying the notification screen on the display unit 22 from the time when the display is started (in the example illustrated in FIGS. 8 to 10, when the broadcast content is switched to the content A). You may limit within a period (for example, 15 to 60 seconds).

(Modification)
Next, a modification of this embodiment will be described. In this modification, the HDR video data indicating the broadcast HDR video may be configured as an HDR signal defined by CTA-861-F. The accompanying information related to the video is described in InfoFrame as a predetermined data area in the HDR signal. FIG. 11 is a diagram illustrating an example of an InfoFrame data configuration according to the present modification. The InfoFrame includes a type code (InfoFrame Type Code) and a plurality of data areas (Data Bytes). The type code is a code indicating the type of accompanying information. The type code of InfoFrame in which luminance information related to the luminance of the video is described is 0x07. The data area is a data area in which accompanying information is described. In the present embodiment, the maximum content luminance level and the maximum frame average luminance level described in InfoFrame may be used as luminance information.

FIG. 12 is a diagram illustrating an example of a data area in which luminance information according to the present embodiment is stored.
In the example illustrated in FIG. 12, information described in each of Data Bytes 3 to 26 is classified into six groups (Groups) for each type of information. The maximum content luminance level and the maximum frame average luminance level are stored in Data Bytes 23 and 25, respectively, and are classified into groups 5 and 6, respectively.

The above-described flash scene flag and flash scene level may be described in InfoFrame. In the example shown in FIG. 13, the flash scene and the flash scene level are stored in Data Bytes 27 and 28, respectively, and are classified into group 2.
The above-described maximum brightness change count, maximum brightness change amount, average brightness change count, and average brightness change amount may be described in InfoFrame. In the example shown in FIG. 14, the maximum brightness change count, the maximum brightness change amount, the average brightness change count, and the average brightness change amount are stored in Data Bytes 27, 28, 29, and 30, respectively, and are classified into group 4.

  Note that the luminance information may be stored in a descriptor area provided for each event identification of MH-EIT instead of MPT. The event identification is identification information for identifying individual programs. Therefore, the accompanying information processing unit 242 of the receiving device 20 can immediately specify the luminance information applied to each broadcast program.

As described above, the reception device 20 according to the present embodiment acquires the incident information related to blinking of the HDR video having a wider range of brightness than the standard broadcast based on the accompanying information associated with the HDR video. A processing unit 242 is provided. In addition, when the reception device 20 determines that the HDR video includes a blinking portion having a blinking rate that is significantly higher than a predetermined blinking level, the notification information processing that outputs the notification information indicating the presence of the blinking portion is performed based on the luminance information. Part 243.
With this configuration, the user can be notified or warned before viewing a high dynamic range video broadcast of the presence of a blinking part that is noticeably blinking. This notification or warning prompts the user to stop viewing the video or reduce the luminance range of the video by an operation.

In addition, the luminance information includes at least one of the number of times the representative value of luminance per predetermined unit time has changed by a predetermined amount or more between frames in the HDR video and the difference between frames of the representative value of luminance per unit time. . Further, the notification information processing unit 243 determines that the blinking portion is included when the number of times is larger than the predetermined number of times or when the difference is larger than the predetermined difference.
With this configuration, a portion of the broadcast HDR video in which a short-time luminance fluctuation amount is larger than a predetermined fluctuation amount is detected as a blinking portion. Therefore, the reception device 20 can quantitatively determine that a blinking portion that is noticeably blinking is included in the broadcast HDR video without providing a means for analyzing a short-time luminance variation. In addition, the number of times the representative value of luminance has changed by a predetermined amount or more between frames or the difference between frames of the representative value of luminance per unit time can be set as a predetermined variation amount based on a user operation. The user can know the blinking degree to be notified or warning in more detail, and can set the blinking degree according to the degree of light sensitivity.

The luminance information includes a representative value of luminance in the HDR video, and the notification information processing unit 243 determines that a blinking portion is included when the representative value is larger than a predetermined representative value.
With this configuration, it is determined that an HDR video that is broadcast with a representative luminance value greater than a predetermined representative value is an HDR video that includes a blinking portion. Therefore, the receiving device 20 determines whether or not the video is an HDR video including a blinking part without quantitatively analyzing the blinking degree of the video. As a predetermined representative value, the representative value of the brightness of the HDR video can be set based on the user's operation, so that the user can know in more detail the blinking degree to be notified or warned, and the photosensitivity The blinking degree can be set according to the degree.

In addition, when the notification information processing unit 243 determines that the blinking portion is included in the HDR video, the reception device 20 includes a video processing unit 222 that adjusts the luminance of the HDR video within the luminance range of the SDR video.
With this configuration, since the brightness of the broadcast HDR video is adjusted within the brightness range of the SDR video, the brightness of the blinking portion of the HDR video is also reduced within the brightness range of the SDR video. Therefore, the user can continue to view the video with the reduced blinking level without performing an operation after recognizing that the blinking section is included in the video.

(Second Embodiment)
Next, a second embodiment of the present invention will be described. About the same structure as 1st Embodiment, the same code | symbol is attached | subjected and the description is used.
FIG. 15 is a schematic block diagram showing the configuration of the broadcast system 1 according to this embodiment. In the example illustrated in FIG. 15, the broadcasting system 1 is configured as a broadcasting / communication cooperation system including the transmitting device 10, the receiving device 20, and the server device 30. The server device 30 is, for example, a server device managed by a broadcaster or a program provider.

  The communication transmission path CT is a transmission path for bidirectionally transmitting various data between the server device 30 and the receiving device 20. The communication transmission line CT includes, for example, a wide area communication network such as the Internet or a public wireless communication network. The communication transmission line CT may include a local area network (LAN) or a dedicated access network in part. Note that transmission (or transmission, reception) of various data via the communication transmission path CT may be referred to as “transmission (or transmission, reception) by communication”.

  When receiving an application request signal from the receiving device 20, the server device 30 transmits an application program (hereinafter referred to as an application) to the receiving device 20 as a response. The application request signal is a signal that indicates a request for the target application. The application is described in a predetermined description language (for example, HTML5), and commands for realizing various functions related to program presentation are described. Examples of application functions will be described later.

  The accompanying information acquisition unit 110 (see FIG. 2) of the transmission apparatus 10 according to the present embodiment further acquires application control information, describes information indicating the presence of the acquired application control information in the MPT, and includes the MPT. Generate service information. The application control information includes information for controlling execution such as URL (Uniform Resource Locator) of the server device 30 and application start / stop as acquisition destination information of the application. The control information is represented, for example, as an application information table (MH-AIT: Application Information Table) having a predetermined data format. In the present embodiment, the application may include an acquisition command for luminance information of the video of the program. The acquisition command includes, for example, the address of a device in which luminance information is arranged as acquisition destination information and the file name of a data file in which the luminance information is stored.

  The receiving device 20 acquires the luminance information by performing the process instructed by the command described in the application. The receiving device 20 performs the process of adjusting the luminance of the video described above using the acquired luminance information. In addition, when the receiving device 20 determines that the video broadcast based on the acquired luminance information is an HDR video and the video includes a blinking portion, the receiving device 20 outputs the notification information described above. If the application includes a luminance information acquisition command or the application includes luminance information, the luminance information may be omitted from the MPT, MH-EIT, or HDR signal.

  The application control information and the application also include accompanying information related to the provision of the program, but are processed as an information unit separate from the MMT-SI. The multiplexing unit 140 further multiplexes the application control information to generate multiplexed data. The separation unit 213 (see FIG. 16) of the reception device 20 further separates the application control information from the multiplexed data input from the demodulation unit 211, and outputs the separated application control information to the associated information processing unit 242.

(Receiver)
Next, the configuration of the receiving device 20 according to this embodiment will be described. FIG. 16 is a schematic block diagram illustrating a configuration of the receiving device 20 according to the present embodiment.
The receiving device 20 according to the present embodiment further includes a communication unit 260.
The communication unit 260 outputs various reception data received from the server device 30 connected via the communication transmission path CT to the control unit 240, and transmits various transmission data input from the control unit 240 to the server device 30. To do. The communication unit 260 is, for example, a communication interface.

The accompanying information processing unit 242 further includes an application control unit 244 and an application execution unit 245.
The application control unit 244 acquires an application based on the application control information input from the separation unit 213, and controls processing instructed by a command described in the acquired application. Note that performing the processing instructed by an instruction described in the application is called “execution of application” or “execution of application”.

  The application control unit 244 extracts application acquisition destination information from the application control information, and transmits an application request signal to the server device 30 indicated by the extracted acquisition destination information. The application control unit 244 receives an application from the server device 30 as a response, and outputs the received application to the application execution unit 245. The application control unit 244 controls the application execution unit 245 to execute the application based on various commands included in the application control information.

  The application execution unit 245 executes the application input from the application control unit 244. The application execution unit 245 causes other functional units to execute processing related to the presentation of the video indicated by the program data based on a command described in the application. For example, the application execution unit 245 transmits a luminance information request signal to the device instructed by the acquisition command described in the application via the communication unit 260. The application execution unit 245 receives luminance information from the device via the communication unit 260 as a response to the luminance information request signal. Further, the application execution unit 245 may cause the video processing unit 222 to execute the above-described luminance adjustment processing based on the acquired luminance information. Based on the luminance information acquired by the notification information processing unit 243, the application execution unit 245 includes a blinking portion in which the broadcast video is an HDR video and the video has a blinking level that is significantly higher than a predetermined blinking level. Whether the notification screen data read from the storage unit 250 is output to the video processing unit 222 as notification information.

(Application control)
Next, an example of application control according to the present embodiment will be described. The application control information includes control information such as a start instruction (AUTOSTART), standby (PRESENT), and termination (KILL). FIG. 17 is a diagram illustrating an example of application control according to the present embodiment. The example illustrated in FIG. 17 indicates that the application control unit 244 starts execution based on a start instruction and ends execution based on an end instruction for an already acquired application. The application instructed to start includes, for example, the acquisition command, notification command, and adjustment command described above. The notification command is a command for causing the notification information processing unit 243 to output the notification information to the video processing unit 222 when determining that the HDR video includes a blinking part based on the acquired luminance information. The adjustment command is a command for causing the video processing unit 222 to perform video luminance adjustment processing based on the acquired luminance information. The time when the application control unit 244 instructs to start is, for example, the later of the start time of the program and the time when the acquisition of the application is completed (the time when reception starts in the middle of the broadcast time). The time when the application control unit 244 instructs to end is, for example, the earlier of the end time of the program or the end of reception of the program during the broadcast time.

(Application execution example)
Next, an application execution example will be described. FIG. 18 is a diagram illustrating an execution example of an application according to the present embodiment.
FIG. 18A shows an example of a notification screen (notification screen Dg01) displayed on the display unit 22. The notification screen Dg01 is an example of display information that the application execution unit 245 displays on the notification information processing unit 243 in accordance with the notification command. The notification screen Dg01 is displayed overlapping within a predetermined range from the lower right corner of the program video. The notification screen Dg01 displayed at this display position does not significantly disturb the viewing of the program video by the user. The notification screen Dg01 includes a message, a “Yes” button, and a “No” button. The message includes a notification message “This content includes a flickering scene” indicating that the video to be broadcast contains a flickering portion. The message also includes a guidance message “Do you want to adjust the brightness?” For prompting the user to determine whether or not the brightness range of the video should be narrowed.

  When the “Yes” button is pressed in response to a user operation, the application execution unit 245 causes the notification information processing unit 243 to start processing indicated by the adjustment command. When the “No” button is pressed or when the cross mark at the upper right corner of the notification screen Dg01 is pressed, the application control unit 244 ends the operation instructed by the application. At this time, the application execution unit 245 causes the notification information processing unit 243 to stop displaying the notification screen Dg01. Note that “pressing” means obtaining an operation signal indicating a position in the display area from the input unit 215 in accordance with a user operation.

  FIG. 18B shows an example of the luminance adjustment screen (luminance adjustment screen Dg02) displayed on the display unit 22 in accordance with the adjustment command described in the application. In the example shown in FIG. 18B, the brightness adjustment screen Dg02 is displayed so as to overlap within a predetermined range from the lower right corner of the video of the program. On the brightness adjustment screen Dg02, a strip-shaped bar Br01, a scroll bar Sc01, and a button Bt01 whose longitudinal direction is directed in the horizontal direction are arranged in order from the top to the bottom.

  The total length of the bar Br01 indicates the luminance range that can be displayed by the display used as the display unit 22, and the length of the brightly painted portion extending from the left end to the right indicates the luminance range of the broadcast video. The scroll bar Sc01 is a screen component for setting a luminance range arbitrarily set by the user (hereinafter referred to as a user-set luminance range) in response to pressing. The arrow at the left end of the scroll bar Sc01 is a screen component for reducing the value set as the upper limit (for example, the maximum luminance) of the user-set luminance range when pressed. The arrow at the right end of the scroll bar Sc01 is a screen component for increasing the value set as the upper limit of the user-set luminance range when pressed. The knob shown in the center of the scroll bar Sc01 is a screen component that is displayed when the position to be pressed is moved and the display position is moved along with the movement. An upper limit of the user-set luminance range that changes according to the amount of movement is set. However, the moving direction is limited to the horizontal direction. Accordingly, by operating the scroll bar Sc01, the user can arbitrarily designate the luminance range that can be displayed on the display unit 22 and the user-set luminance range while looking at the bar Br01. In the example shown in FIG. 18B, the user-set luminance range is limited to the luminance range of the video provided by broadcasting, but may or may not exceed the luminance range that can be displayed by the display unit 22. May be.

The button Bt01 is a screen component for setting the user-set luminance range to a predetermined SDR luminance range when pressed. Therefore, the user can set a predetermined luminance range of the SDR video as the user-set luminance range by pressing the button Bt01.
The application execution unit 245 outputs luminance information indicating the acquired user setting luminance range to the video processing unit 222.

  In the example illustrated in FIG. 18, the maximum luminance of the video indicated by the luminance information is updated to the upper limit of the user-set luminance range as a parameter used by the video processing unit 222 for luminance adjustment. That is, the video processing unit 222 performs luminance adjustment processing using the upper limit of the user-set luminance range instead of the maximum luminance of the video. Therefore, according to the present embodiment, the user is notified that such a video will be broadcast before the video having a flashing level higher than the predetermined flashing level is broadcast, and an arbitrarily set luminance is set. The brightness of the HDR video is adjusted within the range or a predetermined brightness range of the SDR video.

(Modification)
Next, a modification of this embodiment will be described.
The application control unit 244 of the receiving device 20 according to this modification transmits the acquired application to a predetermined other device, and controls processing instructed by a command described in the application transmitted by the other device. That is, in this modification, the application control unit 244 controls the execution of the application in other devices instead of executing the application in the application execution unit 245 (for example, FIGS. 17 and 18). When another device includes a communication unit (not shown), the application control unit 244 may cause the other device to receive the application from the acquisition destination described in the application control information. The communication unit is connected to the server device 30 via the communication transmission line CT and transmits / receives various data. In that case, the communication unit 260 may be omitted in the receiving device 20.

  Other devices provide various control information for controlling the presentation of programs received by the reception device 20 to the reception device 20, and realize a control function for displaying various display information related to the presentation of programs from the reception device 20. It functions as a second display. The input unit 215 of the receiving device 20 outputs an operation signal received from another device instead of the remote controller RC to the control unit 240. The input unit 215 is configured as an input / output interface that transmits various types of data from the control unit 240 to other devices. The notification information processing unit 243 transmits the acquired notification information to another device instead of outputting it to the video processing unit 222. The other device may be an information device including a display unit that displays visual information and an operation unit that receives an operation input. A touch panel integrated as a display panel that is a display unit and a touch sensor that is an operation unit may be used. The other device may be an information device such as a mobile phone (including a so-called smartphone), a tablet terminal device, and a personal computer.

As described above, in the reception device 20 according to the present embodiment, the accompanying information processing unit 242 includes the application control unit 244 that controls execution of a process instructed by a predetermined application based on the application control information. The application causes the reception device 20 or a computer of another device connected to the reception device 20 to acquire luminance information through communication, and the blinking degree of the HDR video broadcast to the notification information processing unit 243 is higher than a predetermined blinking degree. Notification information indicating the presence of a high blinking part is output.
With this configuration, it is possible to notify or warn the user before viewing a high dynamic range video that broadcasts the presence of a blinking part that is noticeably blinking, based on luminance information acquired by communication through processing instructed by the application. . Therefore, the user is prompted to stop viewing the video or reduce the luminance range of the video by an operation based on the luminance information provided from the broadcaster or the content provider via communication. Further, the processing instructed by the application may include processing for adjusting the brightness of the HDR video broadcast by the video processing unit 222 to a narrower brightness range, for example, the brightness range of the SDR video. Therefore, the user can continue to view the video with the reduced blinking level without performing an operation after recognizing that the blinking section is included in the video. In addition, the luminance information is acquired by other devices and the notification information is displayed, so that the function of the receiving device 20 can be prevented from being complicated, and the user can be recognized as an additional service in broadcasting.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to the above-described embodiment, and includes a design and the like within a scope not departing from the gist of the present invention. Each structure demonstrated in the above-mentioned embodiment can be combined arbitrarily.

  For example, in the above-described embodiment, the example in which the broadcasting system 1 uses the MMT method as the media transport method has been described, but the present invention is not limited to this. The broadcast system 1 may use, for example, an MPEG-2 TS system, an RTP (Real-time Transport Protocol) system, or the like. Further, the notification information processing unit 243 may cause the loudspeaker unit 23 to reproduce the notification sound as notification information instead of the notification screen or together with the notification screen. In that case, the notification information processing unit 243 outputs notification voice data indicating the notification voice in which the above-described message is uttered to the voice processing unit 232. The voice processing unit 232 mixes the notification voice indicated by the notification voice data input from the notification information processing unit 243 with the voice indicated by the voice data input from the voice decoding unit 231.

The invention described above can also be implemented in the following manner.
(1) An accompanying information processing unit that acquires brightness information related to blinking of a high dynamic range video having a wider range of brightness than a standard broadcasted based on the accompanying information attached to the high dynamic range video, and the brightness information And a notification information processing unit that outputs notification information indicating the presence of the blinking part when it is determined that the high dynamic range video includes a blinking part having a blinking degree that is significantly higher than a predetermined blinking degree. apparatus.

(2) The luminance information includes the number of times the luminance representative value per predetermined unit time has changed by a predetermined amount or more between frames in the high dynamic range video, and the frame between the luminance representative values per unit time. And the notification information processing unit determines that the blinking portion is included when the number of times is greater than a predetermined number of times or when the difference is greater than a predetermined number of differences. Receiver device.

(3) The luminance information includes a representative value of the luminance in the high dynamic range video, and the notification information processing unit determines that the blinking portion is included when the representative value is larger than a predetermined representative value. The receiving device of (1).

(4) When the notification information processing unit determines that the blinking portion is included in the high dynamic range video, the notification information processing unit includes a video processing unit that adjusts the luminance of the high dynamic range video within the standard luminance range (1 ) To (3).

(5) The accompanying information processing unit includes an application control unit that controls execution of processing instructed by a predetermined application program based on application control information, and the application program is connected to the receiving device or the receiving device. The receiving device according to any one of (1) to (4), wherein a computer of another device acquires the luminance information by communication and causes the notification information processing unit to output the notification information.

(6) A broadcasting system including a transmission device and a reception device, wherein the transmission device broadcasts a high dynamic range video having a wider range of brightness than a standard and accompanying information associated with the high dynamic range video. The reception device includes luminance information related to blinking of the high dynamic range image based on the incidental information, and a predetermined blinking level for the high dynamic range image based on the luminance information. And a notification information processing unit that outputs notification information indicating the presence of the blinking part when it is determined that the blinking part having a remarkable blinking degree is included.

(7) A second transmission device that transmits the luminance information by communication is provided, the transmission device transmits accompanying information including application control information, and the accompanying information processing unit is configured to perform predetermined processing based on the application control information. An application control unit that controls execution of processing instructed by the application program, wherein the application program obtains the luminance information by communication with a computer of the receiving device or another device connected to the receiving device, and the notification The broadcasting system according to (6), wherein an information processing unit outputs the notification information.

(8) A video acquisition unit that acquires a high dynamic range video having a wider range of brightness than the standard, and additional information including luminance information about a blinking portion that has a blinking level that is significantly higher than a predetermined blinking level in the high dynamic range video. And a transmission unit that transmits a broadcast signal in which the high dynamic range video and the accompanying information are multiplexed.

(9) Accompanying information processing step of acquiring luminance information related to blinking of a high dynamic range image having a wider range of luminance than a standard broadcast to a computer of the receiving device based on the accompanying information associated with the high dynamic range image; And a notification information processing step of outputting notification information indicating the presence of the blinking portion when it is determined that the high dynamic range image includes a blinking portion having a blinking rate that is significantly higher than a predetermined blinking rate based on the luminance information. And a program to execute.

  Further, a program for realizing the functions of the transmission device 10, the reception device 20, the server device 30, and other devices described above is recorded on a computer-readable recording medium, and the program recorded on the recording medium is stored in a computer system. The transmission device 10, the reception device 20, the server device 30, and other devices may be realized by causing the device to read and execute. The program is a separate program from the application program described in the second embodiment, but some of the functions may be realized based on the application program. Here, “loading and executing a program recorded on a recording medium into a computer system” includes installing the program in the computer system. The “computer system” here includes an OS and hardware such as peripheral devices. Further, the “computer system” may include a plurality of computer devices connected via a network including a communication line such as the Internet, WAN, LAN, and dedicated line.

The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. As described above, the recording medium storing the program may be a non-transitory recording medium such as a CD-ROM. The recording medium also includes a recording medium provided inside or outside that is accessible from the distribution server in order to distribute the program. The code of the program stored in the recording medium of the distribution server may be different from the code of the program that can be executed by the terminal device. That is, the format stored in the distribution server is not limited as long as it can be downloaded from the distribution server and installed in a form that can be executed by the terminal device.

  Note that the program may be divided into a plurality of parts, downloaded at different timings, and then integrated in the terminal device, or the distribution server that distributes each of the divided programs may be different. Furthermore, a “computer-readable recording medium” holds a program for a certain period of time, such as a volatile memory (RAM) inside a computer system that becomes a server or client when the program is transmitted via a network. Including things. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, and what is called a difference file (difference program) may be sufficient.

DESCRIPTION OF SYMBOLS 1 ... Broadcasting system, 10 ... Transmission apparatus, 110 ... Accompanying information acquisition part, 120 ... Video coding part, 130 ... Audio | voice coding part, 140 ... Multiplexing part, 150 ... Error correction coding part, 160 ... Modulation part, DESCRIPTION OF SYMBOLS 170 ... Transmission part, 20 ... Receiving device, 22 ... Display part, 23 ... Loudspeaker part, 210 ... Broadcast receiving part, 211 ... Decoding part, 212 ... Error correction part, 213 ... Separation part, 215 ... Input part, 221 ... Image | video Decoding unit, 222 ... Video processing unit, 223 ... Display control unit, 231 ... Audio decoding unit, 232 ... Audio processing unit, 233 ... Amplifier, 240 ... Control unit, 241 ... Channel selection unit, 242 ... Attached information processing unit, 243 ... Notification information processing unit, 244 ... application control unit, 245 ... application execution unit, 250 ... storage unit, 260 ... communication unit, BT ... broadcast transmission path, BS ... broadcast satellite, CT ... communication transmission path, RC Control unit

Claims (1)

Accompanying information processing unit for acquiring luminance information related to blinking of a high dynamic range image having a wider range of brightness than a standard broadcasted based on the accompanying information associated with the high dynamic range image;
A notification information processing unit that outputs notification information indicating the presence of the blinking part when it is determined that the high dynamic range image includes a blinking part having a blinking rate that is significantly higher than a predetermined blinking level based on the luminance information; With
The luminance information includes the number of times that the representative value of the luminance per predetermined unit time has changed by a predetermined amount or more between frames in the high dynamic range video, and the difference between frames of the representative value of the luminance per unit time. Including at least one of
The notification information processing unit determines that the blinking portion is included when the number of times is greater than the predetermined number of times, or the difference is greater than the predetermined difference, causes the display unit to display a setting menu screen, and A receiving device that sets the predetermined number of times or the predetermined difference in accordance with.

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