JP2006186442A - Television receiver, control program for television receiver, and broadcast distribution method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a television receiver for detecting a viewer when main channels of High Vision broadcast programs are switched into a plurality of sub channels of standard broadcast programs and a television receiver capable of automatically selecting a sub channel desired by the viewer. <P>SOLUTION: A remote controller 200 generates a channel selection signal to select one main channel or one sub channel from a plurality of received main channels or sub channels in response to the operation of the remote controller. A main body apparatus 100 detects the viewer for viewing the television receiver at present in response to the operation of the remote controller 200 and selects a sub channel including viewer prescribing information in matching with the detected viewer when the main channel selected by the channel selection signal generated by the remote controller 200 is switched into a plurality of sub channels, respectively, including the viewer prescribing information for prescribing the viewing object person. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a television receiver that receives terrestrial digital broadcasting, a control program for the television receiver, and a broadcast distribution method.

In terrestrial digital broadcasting, which began broadcasting in some areas from December 2003, multiple types of information are multiplexed with the transport stream of the MPEG-2 system by the OFDM (Orthogonal Frequency Division Multiplexing) method, The 6 MHz band is divided into 13 segments for transmission. Furthermore, it is planned that a plurality of standard broadcasts can be performed by 3 segments out of 13 segments. Therefore, when sports broadcasts such as professional baseball and soccer on the main channel by high-definition broadcasting are extended, the main channel is switched to standard broadcasting on multiple subchannels, and sports broadcasting is extended on one subchannel. In addition, a service for broadcasting a program originally scheduled on another subchannel is planned.
Considering such a service, when switching from a main channel to a plurality of subchannels, proposals have been made to select one subchannel required by the viewer.

In a TV apparatus and TV system according to a proposal, a TV and a plurality of TV companion apparatuses communicate with each other through a communication link such as infrared rays or optical fibers. The television receives a plurality of different types of information such as audio, video, data, graphics, animation, etc., demultiplexes, selects and distributes the information stream to a plurality of television companion devices. In this distribution, the television embeds an address in the message that identifies the television companion device that is the recipient of the message. (See Patent Document 1)
In another proposed multiplexing system, receiver, and broadcasting device, for DAB (Digital Audio Broadcasting) signals, etc., transmitter identification information included in the signals is extracted on the receiver side, and responses to questionnaires and quizzes are obtained. When outputting data via the telephone network, this transmitter identification signal is transferred together. When analyzing the response data, the transmitter identification information is used to identify and analyze the area. In addition, when the viewer requests local event information or the like, the broadcasting device transmits a broadcast signal obtained by multiplexing necessary data from the transmitter corresponding to the transmitter identification information transferred from the receiver of the viewer. Send. (Patent Document 2)
JP 2000-32363 A JP 2001-136087 A

However, in Patent Document 1 and Patent Document 2, when switching from a main channel of high-definition broadcasting to a plurality of sub-channels of standard broadcasting, one sub-channel is selected by the operation of the viewer. For this reason, for example, in a situation where the main channel is switched to a plurality of sub-channels many times during one hour, an operation for selecting the sub-channel is required each time.
The present invention is for solving such a conventional problem, and detects the viewer when the main channel of the high-definition broadcast is switched to a plurality of sub-channels of the standard broadcast, and the viewer desires. The purpose is to automatically select a subchannel.

  The television receiver according to claim 1 is an operation unit that generates a channel selection signal for selecting one main channel or one subchannel from a plurality of main channels or subchannels to be received according to an operation (embodiment). In FIG. 1) and viewer detection means (corresponding to the CPU 8 in FIG. 3 in the embodiment) for detecting the viewer who is currently viewing according to the operation of the operation means. Viewer specifying information (in the embodiment, FIG. 2) that the main channel (corresponding to the high-definition broadcast of the channel 5 in FIG. 2 in the embodiment) by the channel selection signal generated by the operation means specifies the viewer. A plurality of subchannels (corresponding to the VSI value) in the embodiment shown in FIG. 5-1, 5-2, and 5-3), an automatic selection unit that selects a subchannel including viewer identification information that matches the viewer detected by the viewer detection unit. (Corresponding to the CPU 8 of FIG. 3 in the embodiment).

  In the television receiver according to claim 1, as described in claim 2, the viewer detecting means is a number generated by the operating means (in the embodiment, it corresponds to any one of 1 to 12 in FIG. 9). In other words, the viewer may be configured to detect the viewer who is currently viewing.

  In the television receiver according to claim 2, as described in claim 3, the operation means is a finger that is in contact with a specific operator (corresponding to the power pad 201 in FIGS. 4 and 5 in the embodiment). The image of the fingerprint and the input number are registered in advance as viewer registration information in predetermined storage means (in the embodiment, corresponding to the ID memory 24 in FIG. 6), and an operation for starting the reception of the television broadcast (the embodiment) (Corresponding to a power-on operation on the main device 100), a fingerprint image of a finger that is in contact with a specific operator and an image registered in the storage means are collated with the current viewing It may be configured to generate a person's number.

  In the television receiver of claim 1, as described in claim 4, the viewer detection unit is an imaging unit that captures the appearance of the viewer at the start of the reception of the television broadcast (in the embodiment, in FIG. A configuration may be adopted in which a viewer who is currently viewing is detected based on an image taken by a camera 13.

  According to a fifth aspect of the present invention, there is provided a control program for a television receiver that generates a channel selection signal for selecting one main channel or one subchannel from a plurality of main channels or subchannels to be received according to an operation. , A second step of detecting a viewer who is currently viewing, and a main channel based on a channel selection signal generated by the first step (corresponding to the high-definition broadcast of channel 5 in FIG. 2 in the embodiment). Is) a plurality of sub-channels (in the embodiment, corresponding to the channel 5-1 in FIG. 2, (Corresponding to 5-2, 5-3)), the vision detected by the second step A third step of selecting the sub-channels including viewer identification information that matches the user, to run.

  In the control program according to claim 5, as described in claim 6, the second step is a number generated by the first step (in the embodiment, any number from 1 to 12 in FIG. 9). It may be configured to detect a viewer who is currently viewing based on

  In the control program according to claim 6, as described in claim 7, the first step is brought into contact with a specific operator (in the embodiment, corresponding to the power supply pad 201 in FIGS. 4 and 5). The image of the finger fingerprint and the input number are registered in advance as viewer registration information in predetermined storage means (corresponding to the ID memory 24 in FIG. 6 in the embodiment), and an operation for starting reception of television broadcasting (implementation) (In the embodiment, this corresponds to a power-on operation for the main body device 100), and the image of the fingerprint of the finger touching the specific operation element is compared with the image registered in the storage means and currently viewed. It may be configured to generate a viewer number.

  In the control program according to claim 5, as described in claim 8, the second step includes imaging means for imaging a viewer's appearance at the start of reception of a television broadcast (in the embodiment, the camera of FIG. 3). The viewer may be configured to detect the viewer who is currently viewing the video based on the image obtained by (1).

  The broadcast distribution method according to claim 9 is a method in which when a high-definition broadcast by a main channel is being distributed and when switching to a standard broadcast of a plurality of subchannels, a viewer who specifies a viewer target in the program identification information of each subchannel The configuration is such that specific information is added and distributed.

  In the broadcast distribution method according to claim 9, as described in claim 10, the standard broadcast of the plurality of subchannels may be an advertisement broadcast inserted at any time during the distribution of the high-definition broadcast by the main channel. Good.

  According to the present invention, when switching from a main channel of high-definition broadcasting to a plurality of sub-channels of standard broadcasting, an effect is obtained that a viewer can be detected and a sub-channel desired by the viewer can be automatically selected. It is done.

Embodiments of a television receiver according to the present invention will be described below with reference to FIGS.
FIG. 1 shows the configuration of a system to which a television receiver that receives terrestrial digital broadcasting is applied. The television receiver is composed of a main device 100 and a remote controller 200. Main device 100 receives broadcast radio waves of a plurality of channels received from antenna 1, receives infrared IR emitted by a channel selection operation by remote controller 200, selects a broadcast signal of one channel, and broadcasts it. . The main device 100 is connected to a network 300 such as the Internet. The network 300 is connected to a server 400 that aggregates information on channels selected in the main device 100, and the server 400 and the broadcast station 500 are connected by a dedicated line. The broadcast station 500 analyzes the audience rating of the programs compiled by the server 400 and negotiates with the sponsor about the advertisement broadcast distributed. Each sponsor requests an advertisement broadcast even for a high advertising fee for a program with a high audience rating.

  FIG. 2 shows an example of high-definition broadcasting at a broadcasting station of channel 5 corresponding to the flow of time. As shown in this figure, during the broadcast of a high-definition broadcast from 3 pm to 4 pm, three CM broadcasts provided by a sponsor of a certain pharmaceutical company are broadcast for 3 minutes on a subchannel standard broadcast. In each subchannel, VSI representing viewer specifying information for specifying a target viewer is added to PSI (program specifying information). That is, the VSI of the CM broadcast of male cosmetics targeting adult men is 2, the VSI of the CM broadcast of female cosmetics targeting adult women is 1, and the cold medicine CM broadcast that does not limit viewers 5 is added to each VSI. Actually, several minutes of CM broadcasts are broadcast multiple times during the broadcast of high-definition broadcasts from 3:00 to 4:00. Normally, multiple broadcasts by multiple sponsors are subchannels for each broadcast. Aired on. In addition, a broadcast of a new program provided by the broadcast station itself will be broadcast. Even in this case, in order to improve the broadcasting time, different programs are promoted by multiple subchannels and each program is viewed. VSI is assumed for a person.

  FIG. 3 is a block diagram showing an internal configuration of the main device 100 in FIG. The main device 100 has a configuration in which a signal processing system and a control system are connected by a system bus. That is, as shown in FIG. 1, the signal processing system includes an antenna 1, a tuner 2, a demodulation processing unit 3, an audio / video separation unit 4, an audio decoding unit 5, and a video decoding unit 6. It is connected to the. The control system includes a CPU 8, a ROM 9, a RAM 10, an operation unit 11, an infrared interface (I / F) 12, and a camera 13, and each is connected to the system bus 7.

  In the signal processing system, the tuner 2 selects a digital terrestrial broadcast of one channel from the digital terrestrial broadcast received via the antenna 1, removes the carrier wave, and compresses and encodes an audio signal, a video signal, A digital signal of a transport stream (TS) such as character information is output to the demodulation processing unit 3. The demodulation processing unit 3 branches the digital signal output from the tuner 2 and selectively selects the gate G1, the gate G2, and the digital signal selected by the gate G2 into three digital signals according to the frequency. BPF2a, BPF3b, and BPF3c that are band pass filters, a demodulator 3d that demodulates the digital signal output from the gate G1, and a demodulator 3e that demodulates the digital signal output from the BPF2a, BPF3b, and BPF3c, respectively. Yes. The demodulator 3 d and demodulator 3 e output the demodulated digital signal to the audio / video separator 4. The audio / video separation unit 4 separates the digital signal output from one of the demodulation unit 3d and the demodulation unit 3e into an audio signal and a video signal, and outputs them to the audio decoding unit 5 and the video decoding unit 6, respectively. . The audio decoding unit 5 decodes the audio signal output from the audio / video separation unit 4 and outputs the audio to a speaker (not shown). The video decoding unit 6 decodes the video signal output from the audio / video separation unit 4 and outputs the video to a display (not shown).

  In the control system, the CPU 8 exchanges data and commands with each part of the signal processing system and each part of the control system via the system bus 7 to control the entire main body device 100. The ROM 9 stores in advance a control program executed by the CPU 8 and initial data. The RAM 10 has an area for temporarily storing various data processed by the CPU 8 and also has an area for various registers and flags necessary for executing the control program. The operation unit 11 includes substantially the same switch group as that of the remote controller 200, and inputs commands such as on / off of a television switch and channel change to the CPU 8 according to the operation. The infrared interface 12 receives infrared IR emitted from the remote controller 200 and converts it into an electrical signal, demodulates a modulation signal such as on / off of a television switch, channel change, etc., and inputs the command to the CPU 8. The camera 13 is composed of a digital camera provided in the vicinity of a display (not shown), and takes an image of the viewer. Although not shown in this figure, a database including a non-volatile memory such as a hard disk or a memory card for storing an image captured by the camera 13 is provided in the main unit 100.

  FIG. 4 is a diagram showing a configuration of the remote controller 200. FIG. 4 (1) shows the arrangement of the operation pads of the remote controller 200. In addition to the power supply pad 201, the operation pad includes a channel number pad, a channel up / down pad, a volume adjustment pad, and other necessary pads. Further, an LED (light emitting diode) 202 that emits visible light is provided in the vicinity of the power supply pad 201. The function of the LED 202 will be described later. As shown in FIG. 4B, the viewer first presses the power pad 201 to turn on the power of the main device 100 and perform necessary switch operations such as channel selection and volume adjustment. In addition, the power supply pad 201 is also pressed when the main apparatus 100 is turned off.

FIG. 5 shows a partial configuration inside the remote controller 200. In FIG. 5, the power pad 201 is made of a member that transmits infrared rays and shields visible light, for example, black acrylic, and a part including the upper surface is made of a concave lens 201a, and is inclined at about 45 degrees. The inside of the side surface is a mirror surface that reflects infrared rays.
FIG. 5A illustrates a state in which necessary switch operations such as channel selection and volume adjustment are performed when a television broadcast image is displayed on the display of the main device 100. The LED 203 emits infrared IR that has been pulse-modulated in response to a command such as channel selection or volume adjustment, and passes through the half mirror 204. In this state, since the power supply pad 201 is not pressed, the infrared IR passes through the optical path between the lower part of the power supply pad 201 and the tip of the switch 205 provided on the lower side of the power supply pad 201, and the main body Light is received by the infrared I / F of the apparatus 100.

  FIG. 5B shows a state in which the viewer first presses the power pad 201 to turn on the switch 205 in order to turn on the power of the main device 100. In this state, the optical path of the infrared IR emitted from the LED 203 is blocked by the power pad 201. In this case, unmodulated infrared light IR is emitted from the LED 203 when the switch 205 is turned on. The infrared light IR is changed by the mirror surface 201b of the power pad 201 to the right angle upward, diverged by the concave lens 201a, and irradiated and reflected on the finger that is in close contact with the upper surface of the power pad 201. The reflected infrared rays are converged by the concave lens 201 a, the optical path is changed to a right angle by the mirror surface 201 b, emitted from the power pad 201, the optical path is changed to a right angle by the half mirror 204, and is incident on the CCD 206. . The CCD 206 images the light imaged by the incident infrared rays when the switch 205 is turned on. Therefore, the fingerprint image of the finger is picked up by the CCD 206.

  FIG. 6 is a block diagram showing the internal configuration of the remote controller 200. The CPU 21 is constituted by a one-chip microcomputer having a ROM as a work area having a control program stored therein, a register, a flag, and the like. The CPU 21 also receives an infrared LED 203 that emits infrared IR, a CCD 206 that captures a fingerprint image, an operation unit 23 such as a power pad 201 and a channel switch, a non-volatile ID memory 24 such as a flash ROM, and the like via the system bus 22. It is connected to an LED 202 that emits visible light provided in the vicinity of the power supply pad 201. Note that the operation unit 23 also includes the switch 205 shown in FIG.

  Next, the operation of the remote controller 200 will be described based on the flowchart of the CPU 21 shown in FIGS. FIG. 7 is a flowchart of the main routine. After a predetermined initialization such as clearing the RAM (step SR1), it is determined whether or not the power supply pad 201 is pressed and the switch 205 is turned on (step SR2). When the switch 205 is turned on, it is determined whether or not the ON flag ONF is 0 (step SR3). When the ONF is 0, the ONF is set to 1 (step SR4), and a process for imaging a finger fingerprint is performed (step SR5). That is, when the switch 205 is turned on, as shown in FIG. 5B, the infrared LED 203 emits unmodulated infrared IR, and the CCD 206 images the finger fingerprint. Next, the captured fingerprint data and the fingerprint data stored in the ID memory are collated (step SR6), and it is determined whether or not the captured fingerprint data is unregistered (step SR7). If not registered, a registration process is performed (step SR8).

  FIG. 8 is a flowchart of the registration process. First, the LED 202 of the operation unit blinks (step SR21), prompts the user to input a number, and determines whether or not a number by a channel switch has been input (step SR22). FIG. 9 shows a registration area in the ID memory 24, which identifies a user by number. Next, it is determined whether or not a certain time has elapsed (step SR23). If no number is input even after the certain time has elapsed, the process returns to the main routine. The stored fingerprint data and the input number are linked and registered in the ID memory 24 (step SR24). In addition, the flag RF corresponding to the number is set to 1 in the registration area (step SR25). Thereafter, the LED 202 is turned on and the process returns to the main routine of FIG.

  If the fingerprint data is not yet registered in step SR7 in FIG. 7 or after the fingerprint data is registered in step SR8, on data that is a modulation signal for turning on the power of main device 100 is created (step SR9). ). Next, it is determined whether or not the switch 205 is turned off (step SR10). That is, it is determined whether or not the pressed power pad 201 shown in FIG. 5B is released and the switch 205 is turned off. When the switch 205 is turned off, the infrared IR optical path blocked by the power supply pad 201 is opened, so that the infrared IR is emitted to the main unit 100 (step SR11). In this case, infrared IR modulated by a power-on command and a number that is the viewer's ID is emitted.

  Thereafter, it is determined whether or not the channel has been changed (step SR12). If the channel has been changed, data of the channel number is created (step SR13) and the channel change is made to the main unit 100. Infrared IR is emitted (step SR11). If the channel is not changed, it is determined whether or not the volume has been changed (step SR14). If the volume has been changed, volume data is created (step SR15) and the volume is changed with respect to the main unit 100. Infrared IR is emitted (step SR11). If neither channel change nor volume change is performed, other processing is performed (step SR16). In step SR2, it is determined whether the switch 205 is on.

When ONF is 1 in step SR3 when the switch 202 is turned on, it is a command to turn off the power to the main unit 100, so the ONF is reset to 0 (step SR17) and the LED 202 is turned off (step SR18), off-data is created (step SR19). Then, infrared IR with power off is emitted to the main unit 100 (step SR11).

Next, the operation of the main body apparatus 100 shown in FIG. 3 will be described based on the flowchart of the CPU 8 shown in FIGS.
10 and 11 are flowcharts of the main routine. In FIG. 10, after a predetermined initialization (step SA1), it is determined whether or not infrared rays are received from the remote controller 200 (step SA2). When infrared rays are received, it is determined whether or not it is a power-on command (step SA3). If it is a power-on command, it is determined whether or not an ID which is a viewer number has been received (step SA4). When the ID is received, the ID is stored in the RAM 10 and the flag IDF is set to 1 (step SA5). After setting the IDF or when no ID is received, the tuner 2 and other signal processing systems are turned on (step SA6). Thereafter, the ON flag ONF is set to 1 (step SA7), and reception of the broadcast of the selected channel is started (step SA8). Then, the transport stream in the received signal is detected (step SA9).

  During the reception of the broadcast, it is determined whether the 13-segment high-definition broadcast has been switched to the 3-segment standard broadcast or the 3-segment standard broadcast has been switched to the 13-segment high-definition broadcast (step SA10). . When the broadcast is switched, it is determined whether the three-segment standard broadcast or the 13-segment high-definition broadcast is received as a result of the switching (step SA11). When a three-segment standard broadcast is received, the gate G1 in the demodulation processing unit 3 in FIG. 3 is turned off and the gate G2 is turned on (step SA12), and the received signal is demodulated through the three BPFs 3a, 3b, and 3c. Supply to part 3e. On the other hand, when the 13-segment high-definition broadcast is received, the gate G1 is turned on and the gate G2 is turned off (step SA13), and the received signal is supplied to the demodulator 3d.

  In step SA13, after demodulating the high-definition broadcast with the gate G1 turned on and the gate G2 turned off, or when there is no broadcast switching in step SA10, whether or not infrared rays are received from the remote controller 200 in step SA2. If the infrared ray is received, it is determined whether or not it is a channel change command (step SA14). If the channel is changed, channel selection processing is performed (step SA15). If the received infrared command is not a channel change, it is determined whether or not the command is a volume change command (step SA16). If the volume is changed, the volume is adjusted (step SA17).

If the received infrared command is not a channel change or volume change, it is determined whether or not it is a power-off command (step SA18). If it is a command to turn off the power, ONF is reset to 0 (step SA19), ID is cleared (step SA20), IDF is reset to 0 (step SA21), and infrared light reception is determined in step SA2. To do.
After changing the channel at step SA15, after adjusting the volume at step SA17, or when the power is not turned off at step SA18, the presence / absence of broadcast switching is determined at step SA10.
If no infrared ray is received in step SA2, it is determined whether ONF is 1 (step SA22). If ONF is 1, camera processing is performed (step SA23), and it is determined whether broadcast switching has been performed in step SA10.

  After the gate G1 is turned off and the gate G2 is turned on in step SA12, it is determined whether or not IDF is 1 in the flowchart of FIG. 11 (step SA24). When the IDF is 1, PSI (program specifying information) is acquired from the transport stream (step SA25), and VSI (viewer specifying information) is acquired from the PSI (step SA26). Next, the ID received from the remote controller 200 and stored in the RAM 10 is searched (step SA27), and it is determined whether or not the ID number matches the VSI number (step SA28). When the ID number and the VSI number match, the VSI subchannel is selected (step SA29).

  For example, the high-definition broadcast of the news program on channel 5 shown in FIG. 2 is a commercial broadcast of male cosmetics on channel 5-1, a commercial broadcast of female cosmetics on channel 5-2, and a commercial broadcast of cold medicine on channel 5-3. When the ID stored in the RAM 10 is 2 at the time of switching to, the channel 5-1 with VSI 2 is automatically selected and the male cosmetic commercial broadcast is broadcast. Alternatively, if the ID stored in the RAM 10 is 1, the channel 5-2 with the VSI of 1 is automatically selected to broadcast a female cosmetic commercial broadcast.

If the IDF is 0 in step SA24 in FIG. 11, that is, if the ID is not stored in RAM 10, or if the ID number does not match the VSI number in step SA28, an arbitrary subchannel is selected. (Step SA30).
After the subchannel is selected in step SA29 or step SA30, infrared light reception from the remote controller 200 is determined in step SA2 in FIG.

  12 and 13 are flowcharts of the camera process in step SA23 in FIG. In FIG. 12, first, it is determined whether or not the IDF is 0 (step SB1). When the IDF is 1, that is, when the viewer ID number is stored in the RAM 10, the process returns to the main routine of FIG. When the IDF is 0, the power of the main device 100 is turned on in a state where the viewer ID number is not stored in the RAM 10. In this case, an image of the viewer operating the remote controller 200 is captured (step SB2). Then, separation processing from the background image and other image processing are performed (step SB3).

  Next, it is determined whether or not there are multiple viewers (step SB4). If there are multiple viewers, 5 (family) is set in the ID of the RAM 10 (step SB5). If there is not a plurality of viewers but a single viewer, it is determined whether or not the viewer is an adult woman (step SB6). If the viewer is an adult woman, 1 is set in the ID ( Step SB7). If it is not an adult female, it is determined whether or not the viewer is an adult male (step SB8). If the viewer is an adult male, ID is set to 2 (step SB9). If it is not an adult male, it is determined whether or not the viewer is a child woman (step SB10), and if it is a child woman, ID is set to 3 (step SB11). If it is not a child female, it is determined whether or not the viewer is a male child (step SB12), and if it is a male child, ID is set to 4 (step SB13). After setting any value to ID, IDF is set to 1 (step SB14), and the process returns to the main routine of FIG.

  In step SB12, if the captured viewer is not a child male, that is, if the viewer cannot be identified even if the captured image processing is performed, the past ID stored in the database in the flowchart of FIG. Data that links the captured image of the viewer is searched (step SB15). It is determined whether or not the ID number can be specified by searching the database (step SB16). If the ID number can be specified, that number is set in the ID (step SB17). Then, IDF is set to 1 (step SB18), and the process returns to the main routine of FIG.

  If the ID number cannot be specified by searching the database, the PSI of the currently selected channel is acquired (step SB19), and it is determined whether or not VSI (viewer specifying information) can be acquired from the PSI (step SB19). SB20). If the VSI cannot be acquired, the PSI keyword is searched (step SB21). When VSI can be acquired or when a keyword is searched, an ID number is specified (step SB22). Next, the captured image and the identified ID number are stored in the database (step SB23). Then, the process returns to the main routine.

  As a result of searching for a keyword without a VSI in the PSI, for example, when the keyword is “cooking”, “diet”, “shopping”, “cosmetics”, the viewer is determined to be an adult woman and the ID Is set to 1 and stored in the database together with the captured image. Alternatively, if the PSI keyword is “exploration”, “sports car”, “golf”, “war movie”, etc., the viewer is determined to be an adult male, the ID is set to 2, and the captured image And save it in the database.

As described above, according to this embodiment, the remote controller 200 generates a channel selection signal for selecting one main channel or one subchannel from a plurality of main channels or subchannels to be received according to an operation. . The CPU 8 of the main device 100 detects the viewer who is currently viewing according to the operation of the remote controller 200, and the main channel based on the channel selection signal generated by the remote controller 200 stores the viewer specifying information for specifying the viewer target. When switching to a plurality of subchannels including each, a subchannel including viewer specifying information that matches the detected viewer is selected.
Therefore, when the main channel of the high-definition broadcast is switched to a plurality of sub-channels of the standard broadcast, the viewer can be detected and the sub-channel desired by the viewer can be automatically selected.

The CPU 8 of the main device 100 detects the viewer who is currently viewing based on the number generated by the remote controller 200. In this case, the CPU 21 of the remote controller 200 registers in advance the image of the fingerprint of the finger touching the power pad 201 and the input number in the ID memory 24 as viewer registration information, and performs a power-on operation on the main body device 100. In addition, the fingerprint image of the finger touching the power pad 201 is collated with the image registered in the ID memory 24 to generate the number of the viewer who is currently viewing.
Therefore, the viewer can be reliably identified by a simple operation.
Note that the viewer may be identified by a finger blood vessel pattern instead of the finger fingerprint image. Alternatively, the registration table as shown in FIG. 9 may be displayed on the display of main device 100 and the number may be transmitted from remote controller 200.
In addition, the CPU 8 of the main device 100 detects the viewer who is currently viewing based on the image captured by the camera 13 that captures the appearance of the viewer during the power-on operation of the television broadcast.

  In the above-described embodiment, the invention of the television receiver including the main body device 100 and the remote controller 200 has been described. However, a nonvolatile memory capable of installing a control program in the main device 100 or the remote controller 200 is prepared, and a CD-ROM, DVD, A control program read from an external recording medium such as a memory card or a control program downloaded from a network such as the Internet can be installed in the nonvolatile memory. In this case, the invention of the program is realized.

That is, a control program for a television receiver according to the present invention is:
A first step of generating a channel selection signal for selecting one main channel or one subchannel from a plurality of main channels or subchannels to be received according to an operation, and detecting a viewer who is currently viewing When the main channel based on the channel selection signal generated in the second step and the first step is switched to a plurality of subchannels each including viewer specifying information for specifying a viewer, the second channel And a third step of selecting a sub-channel that includes viewer specifying information that matches the viewer detected by the step.

  The second step detects a viewer who is currently viewing based on the number generated by the first step. In this case, in the first step, the image of the fingerprint of the finger touching a specific operation element and the input number are registered in advance as predetermined registration means as viewer registration information, and reception of a television broadcast is started. The number of the viewer who is currently viewing is generated by comparing the image of the fingerprint of the finger touching the specific operator during the operation with the image registered in the storage means.

  In the second step, a viewer who is currently viewing is detected based on an image obtained by an imaging unit that captures the appearance of the viewer at the start of reception of a television broadcast.

In addition, according to the present invention, the television station 500 shown in FIG. 1 is a new broadcast distribution method, and when switching to a standard broadcast of a plurality of subchannels during distribution of a high-definition broadcast by a main channel, The viewer specifying information for specifying the viewer target is added to the program specifying information and distributed.
Therefore, it is possible to develop a business that provides services to many viewers by simultaneously distributing a plurality of types of programs through subchannels according to different viewer preferences within a limited broadcast time.
In this case, the standard broadcast of a plurality of subchannels is an advertisement broadcast that is inserted as needed during the distribution of the high-definition broadcast on the main channel, so that more advertisement broadcasts can be distributed within the limited broadcast time. Therefore, the sponsor of the advertisement can substantially reduce the cost of the advertisement fee.

The figure which shows the system to which the television receiver of embodiment of this invention is applied. The figure which shows an example of the broadcast data of the terrestrial digital broadcast delivered from the broadcasting station of FIG. The block diagram which shows the internal structure of the main body apparatus which comprises the television receiver of FIG. The figure which shows the structure of the remote control which comprises the television receiver of FIG. The figure which shows the one part structure inside a remote control. The block diagram which shows the internal structure of a remote control. The flowchart of the main routine which shows operation | movement of CPU of a remote control. The flowchart of the registration process in FIG. The figure which shows the viewer registration information registered into ID memory of a remote control. The flowchart of the main routine which shows operation | movement of CPU of a main body apparatus. FIG. 11 is a flowchart of the main routine of the CPU following FIG. 11 is a flowchart of camera processing in FIG. 10. The flowchart of the camera process following FIG.

Explanation of symbols

2 Tuner 3 Demodulation Processing Unit G1, G2 Gate 3a, 3b, 3c Band Pass Filter 3d, 3e Demodulation Unit 4 Audio / Video Separation Unit 5 Audio Decoding Unit 6 Video Decoding Unit 7 System Bus 8 CPU
9 ROM
10 RAM
11 Operation Unit 12 Infrared Interface 13 Camera 21 CPU
22 System bus 23 Operation unit 24 ID memory 100 Main unit 200 Remote control 201 Power pad 202 LED
203 Infrared LED
204 Half mirror 205 Switch 206 CCD
300 network 400 server 500 broadcasting station

Claims (10)

Operation means for generating a channel selection signal for selecting one main channel or one subchannel from a plurality of main channels or subchannels to be received according to the operation;
Viewer detection means for detecting a viewer who is currently viewing according to the operation of the operation means;
When the main channel based on the channel selection signal generated by the operation means is switched to a plurality of subchannels each including viewer specifying information for specifying a viewer, the viewer detected by the viewer detecting means Automatic selection means to select subchannels containing viewer-specific information that matches
A television receiver comprising:   The television receiver according to claim 1, wherein the viewer detection unit detects a viewer who is currently viewing based on a number generated by the operation unit.   The operation means pre-registers the fingerprint image of the finger touching a specific operation element and the input number in a predetermined storage means as viewer registration information, and the specific operation is performed at the start of receiving a television broadcast. 3. The number of the viewer who is currently viewing is generated by collating an image of a fingerprint of a finger touching the operator and an image registered in the storage means. TV receiver.   2. The viewer detection unit detects a viewer who is currently viewing based on an image captured by an imaging unit that captures the appearance of the viewer at the start of reception of a television broadcast. The television receiver described in 1. A first step of generating, in response to an operation, a channel selection signal for selecting one main channel or one subchannel from a plurality of main channels or subchannels to be received;
A second step of detecting viewers currently viewing;
When the main channel based on the channel selection signal generated in the first step is switched to a plurality of subchannels each including viewer specifying information for specifying a viewer target, it is detected in the second step. A third step of selecting a sub-channel that includes viewer-specific information that matches the viewer;
Control program for a television receiver that executes   6. The control program for a television receiver according to claim 5, wherein the second step detects a viewer who is currently viewing based on the number generated in the first step.   In the first step, an image of a fingerprint of a finger touching a specific operator and an input number are registered in advance in predetermined storage means as viewer registration information, and an operation for starting reception of a television broadcast is performed. 7. The number of a viewer who is currently viewing is generated by comparing an image of a fingerprint of a finger touching the specific operator with an image registered in the storage means. A control program of the television receiver described.   6. The second step is characterized in that a viewer who is currently viewing is detected based on an image obtained by an imaging unit that captures the appearance of the viewer at the start of reception of a television broadcast. A control program for the television receiver described in 1.   Broadcast distribution method for adding viewer specific information for specifying a viewer to program specific information of each subchannel when switching to standard broadcast of a plurality of subchannels during distribution of high-definition broadcasts on the main channel .   The broadcast distribution method according to claim 9, wherein the standard broadcast of the plurality of subchannels is an advertisement broadcast that is inserted at any time during the distribution of the high-definition broadcast by the main channel.

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