JP5467644B2 - Area broadcasting system - Google Patents

Description

  The present invention relates to an area broadcasting system.

  The frequency of 1 channel 6 MHz of the broadcasting signal standard ARIB STD-B31 of terrestrial digital broadcasting (ISDB-T) is divided into 14 as shown in the schematic diagram showing the segment arrangement of the terrestrial digital wide area broadcasting of FIG. It consists of 13 segments of 6 kHz and guard bands of both ends 214.3 kHz. The current terrestrial digital broadcasting transmits one high-definition television broadcast (HDTV) program or three standard television broadcasts (SDTV) programs using the 64-value quadrature amplitude modulation (64QAM) method with a large amount of transmission information in the surrounding 12 segments. However, as a one-segment broadcast of digital terrestrial broadcasting (hereinafter abbreviated as 1 segment), video in the OFDM (Orthogonal Frequency Division Multiplexing) system of QPSK that is resistant to transmission errors in the center 0th segment, Transmitting voice and data.

By the way, as shown in the schematic diagram showing the segment arrangement of the terrestrial digital area broadcast in FIG. 10B, the QPSK radio wave of the terrestrial digital broadcast of the central segment # 0 is transmitted with low power in common to a predetermined area such as a municipality. , QPSK radio waves of terrestrial digital broadcasting of segment # 1 to segment # 12 (1 segment) or terrestrial digital radio broadcasting of 3 segments unit are transmitted with low power to each part of a predetermined area such as a housing complex or a village A system (area broadcasting) has been proposed.
Further, a method has been proposed in which the transmission electric field of the central segment # 0 is transmitted stronger than the transmission electric field of the peripheral segment (see Patent Document 1).
Further, it has been attempted to transmit different videos to each segment of 1ch and receive a number of different videos at the mobile phone terminal with a receiving function for each segment of terrestrial digital area broadcasting.

  Broadcast TS (Transport Stream) that transmits a video compression-coded signal for each GOP (Group Of Picture) of a video signal has several areas for multiplexing data broadcasting signals, and is more suitable for the use of multiplexed data It is necessary to select multiple regions. Among the above-mentioned multiple areas, PES (Packetized Elementary Stream) packets are suitable for use in transmitting data for displaying captions and the like superimposed on video (see Non-Patent Document 1).

A frequency region that is vacant in each region because of effective use of the frequency region, which is a finite resource, is called a white space.
In the future, 1Seg is expected to be used for disaster prevention and commercial purposes in municipalities, exhibition halls, large-scale entertainment facilities, shopping streets, etc. for the purpose of effective use of radio white space. (Broadcast service only for a specific area in this way is hereinafter referred to as area broadcasting).
In area broadcasting, radio waves are emitted by selecting frequencies and transmission power used in area broadcasting so that there is no interference with existing broadcasting stations in areas where radio waves are emitted.

When broadcasting or recording a program at a relay site, it is equipped with a TV camera body and a camera control unit that controls the TV camera, communicates with the camera operator, converts the signal format, etc., and switches between several TV cameras. Is called. A general example of this system will be described with reference to FIG.
Video, audio, etc. (hereinafter simply referred to as video) recorded in the relay site 21 are converted into video and audio signal formats by the control unit 31 and transmitted from the broadcaster by the material transmission transmitter 22. Once sent to the station 51.

The video sent to the transmitting station 51 is sent to the head office 41 by the repeater 54, and the video received by the material transmission receiver 23 is organized for sending by the master device 42 at the head office 41, and the broadcast signal transmitter 43 It is sent to the transmitting station 51.
At the transmitting station 51, the broadcast signal received by the broadcast signal receiver 53 is input to the broadcaster 52 and transmitted toward the broadcaster's broadcast area.

Details of the control unit 31 shown in FIG. 4 will be described with reference to FIG.
In FIG. 3, the video captured by the television camera 1 is input to the control unit 31 through the relay cable 2. The input video is converted into a signal format (format) by the converter 3-1, and distributed by the distributor 3-5 to obtain main line outputs 13-1 to 13-4.

The video of the other television camera input to the RET inputs 14-1 to 14-4 is selected by the RET system switch 3-4 and converted to a signal format (format) by the converter 3-1.
Further, it is multiplexed by the general-purpose input 15 and the remote controller controller remote controller data and the multiplexer 3-3 and outputted to the television camera 1. The television camera 1 can check and contact other television cameras, and the camera control unit 31 outputs tally information from a switcher (not shown in FIG. 3) to the camera 1.

  In FIG. 3, according to the tally information from the camera control unit 31, the camera 1 displays an On-Air tally indicating that the captured image of the camera 1 is being used for the red front tally 61 and the red tally 62, and the green Next tally 63 displays a next tally indicating that the image captured by camera 1 is to be used next.

  When broadcasting a program in the vicinity of a relay site, the facilities shown in the related art cover the normal broadcast area of the broadcaster, and are not suitable for broadcasting the captured images of a plurality of target cameras near the relay site. For this reason, the relay site staff cannot confirm the captured images of the plurality of cameras.

JP 2009-212577 A

ARIB Standard STD-B24 “Data Broadcast Coding and Transmission Standards for Digital Broadcasting”

  It is an object of the present invention to allow a relay site staff to confirm video signals output from a plurality of television cameras or a plurality of camera control units at a relay site.

  To achieve the above object, the present invention provides a plurality of television cameras, a camera control unit that controls the television cameras, a transmission conversion unit that converts a plurality of video signals into a one-channel broadcast signal, An area broadcast having an antenna (antenna) for broadcasting a signal, and converting a video signal output from a plurality of television cameras or a plurality of camera control units into a one-channel broadcast signal for area broadcasting System.

  Further, in the above, converting the TS that is multiplexed by multiplexing the information of the currently selected camera number and the next selected camera number in the data multiplexing area of the broadcasting TS (such as a PES packet), and converting to a broadcasting signal; An area broadcasting system characterized by performing at least one of multi-level modulation of 256QAM or more, interleave interval of transmission coding of 0.3 seconds or less, and video compression coding of GOP of 8 fields or less .

  In addition, in the above, a mobile device with a reception function and a video display screen of each segment of the terrestrial digital area broadcast, the mobile device receives the area broadcast, around the video display screen of the mobile device, The broadcast system is characterized by displaying a red tally of the currently selected (On-Air) camera and a green tally of the next selected (Next) camera.

  As described above, according to the present invention, the relay staff confirms the video signals output from the plurality of TV cameras or the plurality of camera control units at the relay site with the mobile phone terminals with the receiving function of the respective segments. Can do.

The block diagram which shows the structure of the upper digital area broadcasting system of one Example of this invention. The block diagram which shows the structure of the terrestrial digital area broadcasting system of one Example of this invention. Block diagram showing the configuration of a conventional TV camera system Block diagram showing the configuration of conventional terrestrial digital wide area broadcasting Block diagram showing the configuration of conventional terrestrial digital area broadcasting Schematic diagram showing segments of digital terrestrial broadcasting ((a) Segment arrangement of terrestrial digital wide area broadcast, (b) Segment arrangement of terrestrial digital area broadcast)

An embodiment of the present invention will be described with reference to FIG. 1 which is a block diagram showing a configuration of a television camera system according to an embodiment of the present invention.
The difference between FIG. 1 of the block diagram showing the configuration of the television camera system of one embodiment of the present invention and FIG. 3 of the block diagram showing the configuration of the conventional television camera system is that a transmission unit 4 is added and the camera is imaged. This means that the video or return input video can be broadcast in the digital terrestrial area.
3, the camera control unit 31 outputs tally information from a switcher (not shown in FIG. 1) to the camera 1. In FIG. 3, according to the tally information from the camera control unit 31, the camera 1 displays an On-Air tally indicating that the captured image of the camera 1 is being used for the red front tally 61 and the red tally 62, and the green Next tally 63 displays a next tally indicating that the image captured by camera 1 is to be used next.

  In FIG. 1, a transmission unit 4 selects a transmission signal, a transmission system switch 4-1 that selects and organizes a transmission signal, a CODEC / TS generator 4-2 that generates a broadcasting TS signal, and converts the TS signal into a broadcasting signal (OFDM modulation). Broadcast signal modulator 4-3, an up converter 4-4 for converting the broadcast signal obtained by the broadcast signal modulator 4-3 into a predetermined broadcast channel, and a PA (power amplifier) 4 for increasing the transmission power as required. -5.

FIG. 2 is a block diagram showing the configuration of terrestrial digital area broadcasting according to an embodiment of the present invention using the television camera system of FIG. FIG. 2 shows an example of recording and broadcasting with three television cameras at a relay site 21 such as a studio, a hall, a stadium, a public stadium, a circuit, a marathon course, and a relay course. The control unit 32-B for the camera 1-B is converted into a broadcast signal by the internal transmission unit 4-B, and the program content is broadcast to the area around the relay site 21 by the transmission antenna 7. In addition, items to be communicated to the relay staff are added as sub-audio or data broadcast of digital terrestrial area broadcasting.
Specifically, information on the currently selected (On-Air) camera number and the next selected (Next) camera number is multiplexed in the PES packet, and the multiplexed TS is converted into a broadcast signal, and the transmission antenna is transmitted. 7 broadcasts the program contents to the area around the relay site 21. Only the portable device 11 encrypted and added with ID (Identification) information can be displayed.

Three relay staff members are mobile devices 11 with ID information attached to each segment of the terrestrial digital area broadcast, such as a mobile phone terminal with a function of receiving each segment of the terrestrial digital area broadcast, and a video display screen. The image captured by the TV camera is confirmed, and the name of the On-Air turtle and the information of the Next camera are confirmed.
The mobile phone terminal 11 with the reception function for each segment of the terrestrial digital area broadcast displays the red tally of the currently selected (On-Air) camera as shown in FIGS. When the green tally of the next (Next) camera is displayed, On-Air and Next can be visually confirmed instantaneously. When the mobile phone terminal 11 is in the horizontal screen, the red tally and the green tally may be displayed around the screen either on the top or bottom of the screen or on the left and right of the screen.

A usage example of 13 segments in one channel of 6 MHz in the transmission system of terrestrial digital television broadcasting will be described.
The center 0 segment transmits the TV camera image of the camera control unit to which the On-Air tally is input from the switcher. Each television camera captured image is transmitted to the segment numbers 1 to 12 of the peripheral segments other than the central 0 segment in accordance with the segment numbers.

  Similar to FIGS. 3 and 1, the camera control units 31-A, 31-B, and 31-C output tally information from the switcher (not shown in FIG. 1) to the cameras 1-A, 1-B, and 1-C. . In FIG. 3, according to the tally information from the camera control units 31-A, 31-B, and 31-C, the red front tally 61-A, 61-B, 61 in the cameras 1-A, 1-B, and 1-C. On-air tally indicating that the captured image of the camera 1 is being used is displayed on C and red tally 62-A, 62-B, 62-C, and green tally 63-A, 63-B, 63 The next tally indicating that the captured images of the cameras 1-A, 1-B, and 1-C are used next is displayed on -C.

  When there are 12 or more TV cameras, the transmission unit 4 in FIG. 1 is used as a switcher for switching the video of the camera control unit, and each segment from 1 to 12 is divided into two, and the video captured by each of the 24 TV cameras is displayed. Assigned to each segment from 1 to 12, the center 0 segment assigns the TV camera image of the camera control unit to which the On-Air tally is input from the switcher, and broadcasts the digital terrestrial area collectively from the switcher.

Although the present invention has been described in detail in the 13 segments of terrestrial digital area broadcasting (ISDB-T), it can be applied to all systems as long as it is a system that broadcasts a broadcast TS having an area where data broadcasting signals are multiplexed. . Specifically, MediaFLO (Forward Link Only), DMB-T (Digital Multimedia Broadcasting for Terrestrial), T-DMB (Terrestrial-Digital Multimedia Broadcasting), DVB-T (Digital Video Broadcasting-Terrestrial), DVB-H (Digital Applicable to various combinations of Video Broadcasting-Handheld (TDMA), Time Domain Multiple Access (TDMA), Time Domain Synchronous (TDS), Code Division Multiple Access (CDMA), OFDM, digital radio, and multimedia broadcasting (ISDB-TSB) .
In the current ISDB-T, the maximum modulation method is 624 kbps with a 16QAM code rate of 1/2, but with DVB-T DTG109, the modulation method is 256QAM code rate of 2/3. If the 1024QAM code rate is 2/3 under test, the transmission area will be narrow, but it will be 624 kbps x 4 x 1.5 = 3.6 Mbps, so it can transmit information equivalent to SDTV, shorten the interleave interval of transmission coding, and reduce the current ISDB-T It is also possible to reduce the delay from about 3 seconds to about 1 second. If MISO (Multi In Single Out) is used, it becomes strong against movement and interference. The band is further doubled by MIMO (Multi In Multi Out), LDPC (Low Density Parity Check) coding, MMSF (Minimum Mean Square Error Soft Interference Simulator), and MIMO iterative decoding. The horizontal polarization, the vertical polarization, and the MIMO iterative decoding further double the bandwidth. The total amount is 3.6 Mbps × 2 × 2 = 14.4 Mbps, so that an amount of information equivalent to HDTV can be transmitted, and the interleaving interval of transmission encoding can be shortened to a delay of about 0.3 seconds. Furthermore, the moving image compression coding method is changed from the current ISDB-T H.264 / AVC to Motion-JPEG-XR or the so-called H.265 low-latency moving image compression coding method, and further transmission coding interleaving. If the interval is shortened, the delay can be shortened to about 0.1 seconds. In other words, it is possible to reduce the delay so that it can be easily used as an on-air return.

  Although the present invention has been described in detail with a mobile phone terminal having a reception function for each segment of terrestrial digital area broadcasting, a reception function of a system for broadcasting a broadcast TS in which an area for multiplexing data broadcasting signals exists to the area and Mobile devices with video display screens are not limited to mobile phone terminals, but can be applied to small personal computers, high-performance mobile phone terminals (smart phones) that are intermediate between mobile phone terminals and personal computers, and PND (Personal Navigation Devise). It can also be applied to.

1, 1-A, 1-B, 1-C: TV camera, 2: Relay cable,
3-1: converter, 3-3: multiplexer, 3-4: RET system switch, 3-5: distributor
4, 4-B: Transmitter, 4-1: Transmission system switch, 4-2: CODEC / TS generator, 4-3: Broadcast signal modulator, 4-4: Up converter, 4-5: PA ( High frequency amplifier),
7: Broadcast antenna, 11: Mobile device with reception function and video display screen for each segment of terrestrial digital area broadcast,
13-1, 13-2, 13-3, 13-4: Main line outputs 14-1, 14-2, 14-3, 14-4: RET input, 15: General-purpose input,
21: Relay site, 22: Transmitter for material transmission, 23: Receiver for material transmission,
24: Relay car,
31, 31-A, 31-B, 31-C, 32, 32-A, 32-B, 32-C, camera control unit 32: simple broadcasting device, 33: transmission system monitor / remote controller 41: head office, 42 : Master device, 43: Broadcast signal transmitter,
51: Transmitting station, 52: Broadcaster, 53: Broadcast signal receiver, 54: Repeater,
61, 61-A, 61-B, 61-C: (On-Air) front tally,
62, 62-A, 62-B, 62-C: (On-Air) red tally,
63, 63-A, 63-B, 63-C: (Next) green tally,

Claims (2)

A plurality of television cameras, a camera control unit that controls the television cameras, a transmission conversion unit that converts a plurality of video signals into one-channel broadcast signals, and an antenna (antenna) for broadcasting the broadcast signals In a broadcasting system that converts video signals output from a plurality of television cameras or a plurality of camera control units into a one-channel broadcast signal and broadcasts in an area, it is currently selected as a data multiplexing area of a broadcast TS (such as a PES packet). The information of the selected camera number and the next selected camera number is multiplexed and converted to a broadcast signal, multi-level modulation of 256QAM or more, interleaving interval of transmission encoding of 0.3 seconds or less, and 8 fields or less Performing at least one of GOP video compression encoding of the GOP System. 2. The broadcasting system according to claim 1 , further comprising: a portable device having a reception function for each segment of terrestrial digital area broadcasting and a video display screen, the portable device receiving the area broadcast, and the video display screen of the portable device. An area broadcasting system characterized by displaying a red tally display of the currently selected (On-Air) camera and a green tally of the next selected (Next) camera.