JP3202555U - Broadcast signal generator - Google Patents

Abstract

There is provided a broadcast signal generation device for easily and immediately using video captured by a consumer device in a broadcast facility. A broadcast signal generation device includes a file input unit capable of inputting a plurality of types of container format files, a container analysis unit (60) for analyzing a container format of a file input to the file input unit, a container A restoration unit (61) for restoring the original video is provided according to the analysis result by the analysis unit and the compression method of the video data included in the file. Also, a video conversion unit (65) that converts the video after restoration by the restoration unit into a video signal having a predetermined number of pixels, and a broadcast signal synchronized with a reference signal based on the video signal after conversion by the video conversion unit A generation unit that generates a video signal and a broadcast signal output unit that outputs a broadcast video signal are provided, and each of these units is mounted on a single casing. [Selection] Figure 6

Description

  The present invention relates to a broadcast signal generator, and in particular, a broadcast signal generator that generates and outputs a video signal suitable for broadcasting business use (hereinafter referred to as a “broadcast video signal”) from video captured by a consumer device. Relates to the device.

  Nowadays, photographing functions of mobile devices such as smartphones and digital cameras have been improved. For this reason, video (including moving images and still images) taken by viewers is increasingly used for television broadcasting. However, the video captured by these consumer devices cannot be used as it is in a broadcasting facility, and needs to be converted into a broadcast video signal, for example, an HD-SDI (High Definition Serial Digital Interface) signal.

  In general, a consumer codec video is converted into a broadcast video signal through a general-purpose PC (Personal Computer), a converter that converts an output signal from the PC into an SDI signal, and an FS (Frame Synchronizer) circuit. The As described above, normally, a broadcast video signal is generated from a consumer-coded video through a plurality of devices.

  On the other hand, Japanese Patent Laying-Open No. 2015-136089 (Patent Document 1) discloses a video playback device that decodes video recorded on a recording medium and outputs the decoded video as an SDI signal.

Japanese Patent Laying-Open No. 2015-136089

  As described above, Patent Document 1 discloses a single device that outputs a video recorded on a recording medium as a broadcast video signal. However, the file format (container format) of the video recorded on the recording medium is limited to MXF (Material eXchange Format) used in professional video equipment, and corresponds to the file format used in consumer equipment. Absent. That is, the apparatus of Patent Document 1 cannot input video files shot by various types of consumer devices.

  The present invention has been made in order to solve the above-described problems, and its purpose is to provide a broadcast signal for easily and immediately using video captured by a consumer device in a broadcasting facility. It is to provide a generation device.

  A broadcast signal generation device according to an aspect of the present invention is a broadcast signal generation device that generates and outputs a broadcast video signal from video captured by a consumer device, and includes a file input unit and a reference signal input unit A container analysis unit, a restoration unit, a video conversion unit, a generation unit, and a broadcast signal output unit. These units are mounted on a single casing. The file input unit can input a plurality of types of container format files. The reference signal input unit inputs a reference signal. The container analysis unit analyzes the container format of the file input to the file input unit. The restoration unit restores the original video according to the analysis result by the container analysis unit and the compression method of the video data included in the file. The video conversion unit converts the video restored by the restoration unit into a video signal having a predetermined number of pixels. The generation unit generates a broadcast video signal synchronized with the reference signal input from the reference signal input unit, based on the video signal converted by the video conversion unit. The broadcast signal output unit outputs a broadcast video signal.

  Preferably, the housing is provided with a plurality of input terminals for mounting each of a plurality of types of recording media, and the file input unit reads a file from the recording media mounted on the input terminals.

  Preferably, the broadcast signal generation device is provided in the housing and a display signal conversion unit that converts the video after restoration by the restoration unit into a display signal for display on a connected monitor, and the display signal Is further provided with a display signal output unit.

  The restoration unit includes a plurality of separation units that extract video data from a file by different methods, and a first selection unit that selects one of the plurality of separation units according to the analysis result of the container analysis unit. It is desirable to include.

  The restoration unit includes a plurality of video decoding units that decode video data using different methods, and a compression method for video data extracted by the separation unit selected by the first selection unit among the plurality of video decoding units. Accordingly, it is desirable to further include a second selection unit that selects one video decoding unit.

  The separation unit may separate and extract the video data and the audio data from the file, and the restoration unit may further include an audio decoding unit that decodes the audio data according to a compression method of the extracted audio data. In this case, the broadcast signal generation device includes an audio conversion unit for converting the restored audio into an audio signal having a predetermined frequency and channel, a video signal after conversion by the video conversion unit, and a conversion by the audio conversion unit. Monitors the processing status of the synthesizing unit, the video decoding unit and the audio decoding unit, and the processing status of the video converting unit and the audio converting unit, and evaluates the conversion delay and feeds back to the separating unit It is desirable to further include a monitoring unit for outputting information.

  According to the present invention, it is possible to easily and immediately use video captured by a consumer device in a broadcasting facility.

It is a figure which shows notionally the signal generator for broadcasting which concerns on embodiment of this invention. 1 is an external view of the front side of a broadcast signal generation device according to an embodiment of the present invention. It is a figure which shows the structural example of the media mounting part provided in the signal generation apparatus for broadcasting which concerns on embodiment of this invention. 1 is a rear view of a broadcast signal generation device according to an embodiment of the present invention. It is a block diagram which shows the outline of a function structure of the signal generation apparatus for broadcasting which concerns on embodiment of this invention. FIG. 6 is a block diagram illustrating a functional configuration of a decoding and HD video conversion unit illustrated in FIG. 5.

  Embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

(About overview)
FIG. 1 is a diagram conceptually showing a broadcast signal generating apparatus 1 according to the present embodiment.

  The broadcast signal generation device 1 is a single device mainly used in broadcasting stations. The broadcast signal generation device 1 generates and outputs an HD-SDI signal as a broadcast video signal from video captured by various consumer devices such as a digital camera, a smartphone, and a mobile phone. Specifically, the broadcast signal generation device 1 decodes the video data of the input file, converts the decoded video data into an HD-SDI signal, and outputs the HD-SDI signal to broadcasting equipment or the like.

  Also, a monitor 9 can be connected to the broadcast signal generating apparatus 1, and the decoded video data is converted into a display signal, for example, an HDMI (High-Definition Multimedia Interface) (registered trademark) signal, and the monitor 9 Can also be output.

  There are a wide variety of container formats for video files shot by consumer devices, such as AVI, MOV, MPEG-2 system, and MP4. Therefore, even if the files are input from the same type of recording medium, the container format is not limited to one type.

  The broadcast signal generation device 1 has a function of analyzing the container format, and can restore the original video according to the analysis result and the video data compression method. Therefore, the video brought in by the viewer can be easily and immediately used in the broadcasting facility only by the single broadcasting signal generation device 1.

  Also, the broadcast signal generation device 1 according to the present embodiment can input files from a plurality of types of recording media (media) such as a memory card and a USB (Universal Serial Bus) memory. It is also possible to input a file via a network such as a LAN (Local Area Network) cable or Wi-Fi (wireless LAN). Therefore, the types of recording media on which video can be recorded vary depending on the type of consumer device. However, according to the broadcast signal generation device 1, video captured and recorded by various consumer devices can be broadcast easily and immediately. It can be made available at the facility.

Specifically, the broadcast signal generation device 1 of the present embodiment mainly has the following characteristics.
i) It is possible to reproduce (restore) video recorded on consumer media.
ii) It can be directly connected to the broadcasting facility (has an FS function).
iii) It conforms to the video input / output signal format of broadcast stations (in the current broadcasting facilities, HD-SDI).
iv) It has VTR-like operability.
v) The structure is integrated and miniaturized.
vi) An external input terminal other than a file (for example, HDMI) is provided.

  The broadcast signal generator 1 having these characteristics i to vi) is considered to be very useful in the broadcasting industry. Hereinafter, an appearance and a configuration example of such a broadcast signal generation device 1 will be described in detail.

(About appearance)
FIG. 2 is an external view of the front side of the broadcast signal generation device 1.

  As shown in FIG. 2, the broadcast signal generation device 1 includes one housing 10 having a cubic shape, for example. All functional units included in the broadcast signal generation device 1 are mounted on the housing 10.

  On the front surface 11 of the housing 10, a medium mounting unit 20 for mounting a plurality of types of recording media, an operation unit 22 for receiving instructions from the user, and an LCD (liquid crystal display) for displaying thumbnails of video files and the like. The unit 23, an LED 24 for notifying the internal status, an audio output terminal 25 for connecting headphones, and an LED 26 for audio output confirmation are provided. Also, an HDMI input terminal 27 for inputting an HDMI signal may be provided.

  FIG. 3 shows a configuration example of the media mounting unit 20. The media mounting unit 20 includes, for example, a media input terminal 21a for mounting a memory stick, a media input terminal 21b for mounting an SD card, an SDHC card, etc., and a media input terminal 21c for mounting a micro SD card, a micro SDHC card, etc. , A media input terminal 21d for mounting a compact flash (registered trademark) card, a micro drive, etc., a media input terminal 21e for mounting an xD picture card, and a USB port 21f.

  As described above, the broadcast signal generating apparatus 1 can input video files from various types of recording media. More specifically, the broadcast signal generation device 1 can read all kinds of memory cards and is equipped with a multi-card reader.

  As shown in FIG. 2, the operation unit 22 includes a power button 221 for instructing power on / off, and a plurality of instruction buttons 222 for instructing start of reproduction, fast forward and rewind during reproduction, and the like. And an instruction button 223 for instructing display of the list screen. The instruction button 222 relating to reproduction is arranged in a cross shape like a well-known VTR (videotape recorder), and is excellent in operability.

  The operation unit 22 further includes an instruction button 224 for switching display contents of the LCD unit 23, an instruction button 225 for switching to HDMI input, and an instruction button 226 for adjusting the volume.

  FIG. 4 shows a rear view of the broadcast signal generation apparatus 1. On the rear surface 12 of the housing 10, a DC power input terminal 31, a LAN terminal 32 for connecting a LAN cable, a USB terminal 33 for connecting a USB cable, and an HDMI terminal for connecting an HDMI cable 34, an SDI output terminal 35 for connecting a coaxial cable for broadcasting, and a REF input terminal 36 for inputting a REF (reference) signal. The HDMI cable enables video transmission from the broadcast signal generator 1 to the monitor 9 (FIG. 1). In this embodiment, two systems of SDI output terminals 35 are provided, and one system can perform OSD (On Screen Display) display.

  As described above, the broadcast signal generation device 1 has a plurality of terminals for inputting video files and a UI (user interface) unit arranged on the front surface 11 side, which is easy to use. The size of the housing 10 of the broadcast signal generating device 1 is compact (1U half rack size) with a width of 25 cm or less, a height of 4.5 cm or less, and a depth of 36 cm or less. Therefore, it is convenient to carry the broadcast signal generator 1. Furthermore, since the broadcast signal generator 1 is driven by a DC power source, it is also optimal for a relay car.

(About functional configuration outline)
FIG. 5 is a block diagram illustrating an outline of a functional configuration of the broadcast signal generation device 1.

  As shown in FIG. 5, the broadcast signal generation device 1 includes, as a control system, a control unit 41 that controls the entire device, a storage unit 42 that stores programs and data, and a timing unit 43 that performs a timing operation. I have. The control unit 41 is electrically connected to the UI unit, that is, the operation unit 22, the LCD unit 23, and the LEDs 24 and 26. In addition, information is transmitted to and received from each unit of the video processing system. The control unit 41 is realized by, for example, a CPU (Central Processing Unit).

  The broadcast signal generation apparatus 1 includes a plurality of media I / Fs (interfaces) 51, a decoding and HD video conversion unit 52, a buffer memory 53, a synchronization circuit 54, and an SDI output I / F 55 as video processing systems. , A decoding and HDMI conversion unit 56, a buffer memory 57, and an HDMI output I / F 58.

  The plurality of media I / Fs 51 correspond to the plurality of (for example, six) media input terminals 21a to 21e shown in FIG. The media I / F 51 reads a video file from recording media attached to the media input terminals 21a to 21e. The media I / F 51 reads into the SDI output system (that is, the decoding and HD video conversion unit 52) and the HDMI output system (that is, the decoding and HDMI conversion unit 56) in accordance with an instruction from the control unit 41. Selectively output video files.

  The decode and HD video conversion unit 52 extracts video data from the video file acquired from the media I / F 51, and decodes (restores) the video data according to the compression method. Also, the decoded video data is converted into an HD video signal. The HD video signal is an example of a video signal having a predetermined number of pixels suitable for broadcasting. The HD video signal standard is an interlaced standard (represented as 1920 × 1080 / 59.94i) with a pixel count of 1920 × 1080 pixels, a field frequency of 59.94 Hz, and a frame rate of 29.97 fps. .

  If the video file also includes audio data, the decoding and HD video conversion unit 52 decodes the audio data according to the compression method for the audio data extracted from the file, and the decoded audio data Is converted into an audio signal having a predetermined frequency and channel suitable for broadcasting. The converted audio signal is combined with the HD video signal and output to the buffer memory 53. A signal obtained by synthesizing the HD video signal and the audio signal is herein referred to as an “audio superimposed HD signal”. The specific functional configuration of the decoding and HD video conversion unit 52 will be described later.

  The synchronization circuit 54 inputs the HD video signal (or audio superimposed HD signal) temporarily stored in the buffer memory 53, and synchronizes the input HD video signal with the REF signal obtained from the REF input terminal 36. The REF signal is a signal required as an input signal in the broadcasting station, for example, a BB (Blac burst) signal or an HD ternary synchronization signal.

  The synchronization circuit 54 functions as a generation unit that generates an HD-SDI signal that is a broadcast video signal. Specifically, the synchronization circuit 54 has a frame memory, and controls writing and reading of the HD video signal to and from the frame memory in synchronization with the REF signal obtained from the REF input terminal 36. Thereby, an HD-SDI signal is generated.

  The SDI output I / F 55 outputs the HD-SDI signal obtained from the synchronization circuit 54 to the broadcasting equipment via the broadcasting cable connected to the SDI output terminal 35 shown in FIG.

  Note that the function of each part of the video processing system may be realized by hardware or executed by software. Alternatively, a part of the video processing system may be realized by hardware, and the rest may be realized by software. When at least a part of the video processing system is realized by software, both the function of the corresponding unit and the function of the control unit 41 are realized by one CPU reading and executing a program stored in the storage unit 42 May be.

  The decoding and HDMI conversion unit 56 extracts video data from the video file acquired from the media I / F 51, and decodes the video data according to the compression method. The decoded video data is converted into an HDMI signal by a known method.

  The buffer memory 57 temporarily stores the HDMI signal output from the decoding and HDMI conversion unit 56. The HDMI signal temporarily stored in the buffer memory 57 is output to the HDMI output I / F 58 in response to a command signal from the control unit 41. As a result, the video stored in the file read by the media I / F 51 is displayed on the monitor 9 connected to the broadcast signal generation device 1.

(Decoding and HD video converter functional configuration)
FIG. 6 is a block diagram showing a functional configuration of the decoding and HD video conversion unit 52. In FIG. 6, for easy understanding, arrows indicating the flow of video and audio are indicated by bold lines, and other signal lines are indicated by thin lines.

  As shown in FIG. 6, the decoding and HD video converting unit 52 includes a restoring unit 61 for restoring the original video and audio, and a video for converting the video and audio into signals in a format suitable for broadcasting, respectively. It includes a conversion unit 65 and an audio conversion unit 68, and a synthesis unit 69 that synthesizes the video signal and the audio signal after conversion by the video conversion unit 65 and the audio conversion unit 68.

  There are a plurality of types of container formats of files that can be handled by the broadcast signal generation apparatus 1 of the present embodiment, which are not uniform. The extraction method (separation method) of video data and audio data from a file is different for each container format. Therefore, the restoration unit 61 includes a plurality of separation units (DeMux) 62 that extract video data and audio data from a file by different methods. In addition, the decoding and HD video conversion unit 52 includes a container analysis unit 60 that analyzes the container format of the input file before the restoration unit 61.

  The container analysis unit 60 reads the contents of the file input from the media I / F 51 and analyzes the container format (data structure) of the file. Specifically, the file extension and the hierarchical structure of the file are analyzed, and the container format of the file is analyzed. This is because consumer-coded video may have different data structures even if the file extension is the same.

  The extension of video files that can be input to the media I / F51 is ".mts", ".mp4" used for consumer handy cameras, ".mov", ".3gp" used for mobile phones, etc. There are more than 10 types such as “.asf”, “.mpg / .mpeg”, “.avi”.

  The container analysis unit 60 selects one separation unit 62 among the plurality of separation units 62 according to the analysis result of the container format (that is, according to the data structure of the input file). In FIG. 6, it is assumed that the selected separation unit 62 is shown.

  The selected separation unit 62 reads the file from the container analysis unit 60, and separates and extracts the video data and audio data according to the data structure. At this time, additional information (meta information) including video time information, audio channel information, and the like is also extracted.

  In the present embodiment, the compression methods (codecs) of the extracted video and audio data are not uniform and there are a plurality of types. The data restoration method (decoding method) differs for each compression method. Therefore, the restoration unit 61 includes a plurality of video decoders (video decoding units) 64 that decode video data using different methods and a plurality of audio decoders (audio decoding units) 67 that decode audio data using different methods. doing. Also, among the plurality of video decoders 64, the video decoder selection unit 63 that selects the video decoder 64 according to the compression method of the video data after separation, and the video data after separation among the plurality of audio decoders 67 And an audio decoder selection unit 66 for selecting the audio decoder 67 according to the compression method.

  There are 10 or more video data compression methods (codecs), such as “AVCHD / MPEG-4”, “AVC / H.264”, “MPEG-4”, “H.264”, “WMV9”. There are 10 or more audio data compression methods (codecs), such as “LPCM”, “AC-3”, “AAC”, “WMA”, “MPEG audio Layer 3”.

  The video decoder selection unit 63 analyzes the video data structure (VIDEO structure) extracted by the separation unit 62. Thereby, the compression method (codec) of video data can be determined. The decoder selection unit 63 selects the (optimum) video decoder 64 corresponding to the compression method of the extracted video data from the plurality of video decoders 64. In FIG. 6, it is assumed that the selected video decoder 64 is shown.

  The audio decoder selection unit 66 analyzes the structure (AUDIO structure) of the audio data extracted by the separation unit 62. Thereby, the compression method (codec) of the audio data can be determined. The decoder selection unit 66 selects the (optimum) audio decoder 67 corresponding to the compression method of the extracted audio data from the plurality of audio decoders 67. In FIG. 6, it is assumed that the selected audio decoder 67 is shown.

  The selected video decoder 64 receives the video data extracted by the separation unit 62 and decodes (restores) the input video data. The restored video signal is output to the video conversion unit 65. Similarly, the selected audio decoder 67 inputs the audio data extracted by the separation unit 62, and decodes (restores) the input audio data. The restored audio signal is output to the audio conversion unit 68.

  The video conversion unit 65 decodes the video based on the meta information (video time information, pixel information, etc.) obtained from the separation unit 62 and the frame rate (original video) obtained from the container analysis unit 60. Data is converted into an HD video signal. Specifically, first, based on the meta information obtained from the separation unit 62, the decoded video data is converted into video data having a predetermined number of pixels. Thereafter, based on the frame rate obtained from the container analysis unit 60, a frame rate conversion process is performed to generate an HD video signal (1920 × 1080 / 59.94i). The converted HD video signal is output to the synthesis unit 69. The frame rate conversion process may be performed by the combining unit 69.

  The audio conversion unit 68 converts the decoded audio data into an audio signal having a predetermined frequency and channel according to the broadcasting standard based on the meta information (audio frequency information, channel information, etc.) obtained from the separation unit 62. Convert. The converted audio signal is output to the synthesis unit 69.

  The synthesizing unit 69 inputs the HD based on the clock information obtained from the container analyzing unit 60, the clock information in the video stream obtained from the video decoder 64, and the clock information in the audio stream obtained from the audio decoder 67. Synthesize video and audio signals. As a result, an audio superimposed HD signal is generated and output to the buffer memory 53 shown in FIG.

  Here, it is difficult for the video decoder 64 to decode in real time the video that has been subjected to consumer codec. That is, there is a possibility that constant restoration data cannot be obtained with a certain amount of data. Then, in the synthesis unit 69, a deviation occurs in the synthesis of the video signal and the audio signal, and the synthesis itself is delayed. This is because consumer equipment has a wider variety of video frame rates and compression rates than commercial equipment.

  Therefore, it is desirable that the decoding and HD video converting unit 52 of the present embodiment includes the monitoring unit 70.

  The monitoring unit 70 monitors the processing status of the video decoder 64 and the audio decoder 67 and the processing status of the HD video conversion unit 65 and the audio conversion unit 68, and evaluates (calculates) a video conversion delay. The monitoring unit 70 outputs feedback information corresponding to the evaluation result to the separation unit 62. Specifically, it is determined how much the reading interval of the file in the separation unit 62 is advanced, and the separation unit 62 is instructed to read the file at a reading interval according to the determination result.

  When receiving the feedback information from the monitoring unit 70, the separation unit 62 changes the file reading interval from the container analysis unit 60 to a reading interval according to the instruction. Thereby, in the synthetic | combination part 69, the shift | offset | difference of the synthetic | combination timing of a video signal and an audio | voice signal can be suppressed.

  Note that the functions of the units shown in FIG. 6 are realized by software. Thereby, size reduction of an apparatus is realizable. However, at least some of the functions of the units illustrated in FIG. 6 may be realized by hardware.

  As described above, the broadcast signal generation device 1 according to the present embodiment is a single device that uses a predetermined standard from video and audio recorded by various consumer devices, as a multi-file player. Broadcast video signals (HD-SDI signals on which audio is superimposed) can be generated and output.

  The decoding and HDMI conversion unit 56 shown in FIG. 5 also has the functions of the container analysis unit 60 and the restoration unit 61. Since the broadcast signal generation device 1 also has an HDMI output function, the content of the video brought in by the viewer can be confirmed once on the monitor 9 before flowing to the broadcasting facility as an HD-SDI signal. . The video displayed on the monitor 9 can be fast-forwarded and rewound by the instruction button 222 of the operation unit 22. At that time, time information of the image being displayed may be displayed on at least one of the monitor 9 and the LCD unit 23.

  Further, while outputting the HD-SDI signal, the image being output may be displayed on the LCD unit 23. Also, video time information may be output from the SDI output terminal 35 together with the HD-SDI signal.

  In addition, the broadcast signal generation device 1 can also convert an HDMI signal input via the HDMI input terminal 27 into an HD-SDI signal so as to be compatible with video of an incompatible codec. As a result, the broadcast signal generation device 1 can restore video in any compression format.

  In the above-described embodiment, an example in which the media I / F 51 acquires only one file has been described. However, when the media I / F 51 acquires a plurality of files, a single file selected by the user is selected. Assume that the decoding and conversion processes described above are performed.

  When the media I / F 51 acquires a plurality of files, it is desirable that the broadcast signal generation device 1 generates thumbnails for identifying each video file and displays the plurality of thumbnails on the LCD unit 23. In this case, when one thumbnail is selected from a plurality of thumbnails, the pointer of the file indicated by the thumbnail is output to the container analysis unit 60 of the decoding and HD video conversion unit 52. Note that the designated file and subsequent files may be processed continuously.

  When generating a thumbnail for each file, it is necessary to extract video data from each file and decode, for example, the top image. Even in this case, the functions of the container analysis unit 60, the separation unit 62, the video decoder selection unit 63, and the video decoder 64 are executed. One thumbnail can be selected from a plurality of thumbnails displayed on the LCD unit 23 by operating the instruction button 222 described above.

  In addition, the broadcast signal generation apparatus 1 can receive only the file designated in another apparatus, when receiving a file from other apparatuses, such as a smart phone, via a network. Therefore, it is possible to protect the privacy of viewers who bring video to the broadcasting station.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  DESCRIPTION OF SYMBOLS 1 Broadcasting signal production | generation apparatus, 9 Monitor, 10 Case, 20 Media mounting part, 21a-21e Media input terminal, 21f USB port, 22 Operation part, 23 LCD part, 24, 26 LED, 25 Audio | voice output terminal, 27 HDMI Input terminal, 31 DC power input terminal, 32 LAN terminal, 33 USB terminal, 34 HDMI terminal, 35 SDI output terminal, 36 REF input terminal, 41 control unit, 42 storage unit, 43 timing unit, 51 media I / F, 52 decoding and HD video conversion unit, 53, 57 buffer memory, 54 synchronization circuit, 55 SDI output I / F, 56 decoding and HDMI conversion unit, 58 HDMI output I / F, 60 container analysis unit, 61 restoration unit, 62 separation Section, 63 video decoder selection section, 64 video decoder, 65 HD video Section, decoder selection portion for 66 voice, 67 audio decoder, 68 sound conversion unit 69 synthesizing unit 70 the monitoring unit.

Claims (6)

A broadcast signal generation device that generates and outputs a broadcast video signal from video captured by a consumer device,
A file input section that can input multiple types of container format files;
A reference signal input section for inputting a reference signal;
A container analysis unit for analyzing a container format of a file input to the file input unit;
According to the analysis result by the container analysis unit and the compression method of the video data included in the file, a restoration unit for restoring the original video,
A video conversion unit that converts the video restored by the restoration unit into a video signal having a predetermined number of pixels;
Based on the video signal converted by the video conversion unit, a generation unit that generates a broadcast video signal synchronized with a reference signal input from the reference signal input unit;
A broadcast signal output unit for outputting the broadcast video signal,
Each of the above sections is a broadcast signal generating device mounted on a single casing. The housing is provided with a plurality of input terminals for mounting a plurality of types of recording media,
The broadcast signal generation device according to claim 1, wherein the file input unit reads a file from a recording medium attached to the input terminal. A display signal conversion unit that converts the image restored by the restoration unit into a display signal for display on a connected monitor;
The broadcast signal generation device according to claim 1, further comprising: a display signal output unit that is provided in the housing and outputs the display signal.   The restoration unit selects a plurality of separation units that extract video data from a file by different methods, and a single selection unit selected from the plurality of separation units according to an analysis result of the container analysis unit The broadcast signal generation device according to claim 1, further comprising: a unit.   The restoration unit compresses video data extracted by a plurality of video decoding units that decode video data by different methods and a separation unit selected by the first selection unit among the plurality of video decoding units. The broadcast signal generation device according to claim 4, further comprising: a second selection unit that selects one video decoding unit according to a method. The separation unit separates and extracts video data and audio data from the file, and the restoration unit further includes an audio decoding unit that decodes audio data according to a compression method of the extracted audio data,
An audio conversion unit for converting the restored audio into an audio signal of a predetermined frequency and channel;
A synthesis unit for synthesizing the video signal after conversion by the video conversion unit and the audio signal after conversion by the audio conversion unit;
A monitoring unit for monitoring the processing status of the video decoding unit and the audio decoding unit and the processing status of the video conversion unit and the audio conversion unit, evaluating a conversion delay, and outputting feedback information to the separation unit The broadcast signal generation device according to claim 5, further comprising:

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