JP4427909B2 - Home server device, video / audio data editing method and video / audio data generation method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a home server device that can analyze, for example, biometric information related to health and edit a video / audio auxiliary signal, and more particularly to a home server device, video / audio suitable for use in transmission / reception of health data corresponding to each scene in a broadcast program. The present invention relates to a data editing method and a video / audio data generation method.
[0002]
[Prior art]
In recent years, an increase in lifestyle-related diseases has become remarkable. It has been pointed out that this lifestyle-related disease progresses due to the accumulation of wrong lifestyle habits, and each user (individual) is trying to improve their life and improve their health. Long-term responses such as maintaining are becoming important.
[0003]
Many homes have instruments and devices for managing the health of users. The user measures and acquires his / her health data (hereinafter sometimes referred to as health data), and the health data is referred to as a health management device (hereinafter referred to as a health management device). )). Here, the health data means vital data such as height, weight, age, sex, and medical data, and lifestyle data such as data related to diet, exercise, and life.
[0004]
The health management device is adapted to predict disease, risk, proper exercise prescription (exercise menu) and proper meal prescription based on the input health data. In addition, vital data and lifestyle data are input using a biological sensor such as a heart rate monitor or a portable pedometer. The input data relates to health and is referred to as biological information (biological information data).
[0005]
As for the health of each user, there are a number of television programs related to health (hereinafter sometimes abbreviated as “programs”) that are broadcast on television. There are many types of medical care. Each program has a different length of program time, and the contents range from those that are easy to understand and easy to understand to those that are intended to be sophisticated and accurate.
[0006]
In recent years, with the spread of cable television, the CATV (Cable Television or Community Antenna Television System) station uses video and audio data (video and audio signals) in which television programs and movie works are digitized using optical fibers. It provides services to be distributed to each home.
For example, hard disk video recorders have been developed as household appliances due to advances in hard disk technology. This hard disk video recorder records a program on a hard disk. By using this hard disk video recorder, a user can enjoy a desired program at a desired time as compared with a conventional home video tape recorder (VTR). In addition to this, the user can reproduce and view the recorded program in parallel with the recording of the program currently being broadcast.
[0007]
Further, the user can easily make a program reservation or personal use by using an electronic program guide transmitted superimposed on a radio signal in a frequency band assigned for broadcasting (hereinafter abbreviated as a broadcast wave signal). You can search for programs according to your preferences and always watch the latest news programs. Thus, the hard disk video recorder is also called a home server device (home server) in the sense that it simply records a program.
[0008]
As described above, the user can obtain video / audio data such as television program data (television program signal) from a CATV station or a data distribution company using an optical fiber. The user can also obtain video / audio data via the Internet.
In Japan, the NTSC (National Television System Committee) system is adopted as a television broadcasting system. In the NTSC system, as is well known, one screen is composed of 525 scanning lines, and among these scanning lines, 262.5 (referred to as the first field) scanning lines are 60. The first field and the second field are scanned so that the remaining 262.5 scanning lines (referred to as the second field) are scanned in the next 1/60 second period. The field is scanned alternately.
[0009]
In the NTSC system, there is a period in which information data is not written in the vertical blanking period (time required for scanning from the upper left to the lower right of the screen). For this reason, the broadcasting station uses the vertical blanking period to superimpose secondary information. In other words, the broadcast station (or the transmitter of the relay station) multiplexes this secondary information into program data as auxiliary data (auxiliary signal) of digital data.
[0010]
[Problems to be solved by the invention]
However, many health care devices are not designed to be able to report proper exercise prescriptions to each of the users, and those for which the health management device prepares the exercise prescriptions in advance, The objects that can be handled by the health care device are limited to still images, moving images, characters, or sounds. Therefore, the display by the health care device is uniform with little change, and the user is easily bored, and it is difficult for the user to use the health care device for a long period of time. is there.
[0011]
Furthermore, a large number of broadcast programs related to the health of users are broadcast, but the broadcast form has a characteristic of one-to-many. For this reason, the program content becomes average and cannot be satisfied by each user.
The present invention was devised in view of such problems, and can edit and reproduce related processing, video, audio and auxiliary data, and re-edit and reproduce programs suitable for the health condition of each user. It is a first object of the present invention to provide a home server device, a video / audio data editing method, and a video / audio data generation method.
[0012]
In addition, the present invention provides a home server device and video / audio data that can provide a program suitable for the health condition of each user without changing any existing television broadcasting system format by using auxiliary data. It is a second object of the present invention to provide an editing method and a method for generating video / audio data.
[0013]
[Means for Solving the Problems]
For this reason, the home server device of the present invention demodulates content data having main data composed of a plurality of unit data related to video and audio and sub data including attribute information data assigned to each unit data, A decoding unit that outputs sub-data, a storage unit that stores main data and sub-data output from the decoding unit, sub-data stored in the storage unit, and biological information data related to health. A data editing unit that outputs an instruction signal for instructing an interlocking operation and a sub-data stored in the accumulating unit based on the instruction signal output by the interlocking unit and that outputs reproduction data obtained by reproducing the main data. -It is characterized by comprising an output section (claim 1).
[0014]
Further, the home server device of the present invention includes video / audio data composed of a plurality of unit video / audio data corresponding to each scene in a program, auxiliary data including program attribute information data assigned to each of the unit video / audio data, and A decoding unit that demodulates program data and outputs video / audio data and auxiliary data, a storage unit that stores video / audio data and auxiliary data output from the decoding unit, and auxiliary data stored in the storage unit And an interlocking unit that outputs an instruction signal for instructing an interlocking operation associated with each of the biometric information data related to health and an auxiliary data stored in the storage unit based on the instruction signal output by the interlocking unit, and a video It is characterized by having a data editing / output unit that outputs playback data that has played back audio data. Claim 2).
[0015]
Furthermore, a playback unit that plays back playback data output from the data editing / output unit may be provided (Claim 3), wherein the program is a program related to health, and a decoding unit is provided for each scene in the program. Correspondingly, at least the scene name, the time, the number of repetitions of the unit scene, and the health data relating to the physical load can be output as auxiliary data (claim 4).
[0016]
The interlocking unit may be configured to output at least information related to physical condition and biological rhythm as an instruction signal (Claim 5), and outputs biological state data related to the biological state based on the biological information data. A biological state output unit and an instruction output unit that compares the biological state data and health data and outputs an instruction signal can also be configured.
[0017]
In addition, the biological state output unit may include a first table that stores biological information data and biological state data in association with each other (claim 7).
Further, the instruction output unit relates to a comparison unit that compares the biological state data and the health data and outputs a comparison result, and based on the comparison result, shortens, extends and deletes a required time in each scene, and changes contents A second table for storing the increase / decrease value as an instruction signal may be provided (claim 8).
[0018]
Furthermore, the interlocking unit can be configured to receive a plurality of pieces of biological information data (claim 9).
The decoding unit may be configured to obtain the program data from a wireless signal using a predetermined method (claim 10), and the program data is a wired method or a recording medium on which information data is recorded. May be obtained from at least one of the following (claim 11).
[0019]
In addition, the video / audio data editing method of the present invention includes a period for transmitting main data including a plurality of unit data related to video / audio and a period for transmitting sub-data including attribute information data assigned to each unit data. A method of editing video and audio data comprising: demodulating content data having main data composed of a plurality of unit data related to video and audio and sub data including attribute information data assigned to each unit data; A decoding step for outputting data and sub-data, a storage step for storing main data and sub-data output in the decoding step in a storage unit for storing data, sub-data stored in the storage unit, and health A linked operation step that outputs an instruction signal instructing the linked operation, linked to each of the biological information data related to Sub-data editing step for editing the sub-data stored in the storage unit based on the instruction signal output in the operation step, and the main data stored in the storage unit based on the instruction signal output in the interlocking operation step The present invention is characterized by comprising a data editing / output step for outputting reproduction data obtained by reproducing the data and a reproduction step for reproducing the reproduction data output in the data editing / output step (claim 12).
[0020]
The video / audio data editing method of the present invention includes a period for transmitting video / audio data composed of a plurality of unit video / audio data corresponding to each scene in the program, and a program attribute assigned to at least each of the unit video / audio data. A method of editing video / audio data having a period for transmitting auxiliary data including information data, wherein the video / audio data includes unit video / audio data corresponding to each scene in a program, and at least a program attribute assigned to each scene A decoding step for demodulating program data having auxiliary data including information data and outputting video / audio data and auxiliary data, and storing the video / audio data and auxiliary data output in the decoding step for data storage The accumulation step accumulated in the department, the auxiliary data accumulated in the accumulation section and the biological information data on health A linked operation step for outputting an instruction signal for instructing the linked operation, and an auxiliary data editing step for editing the auxiliary data stored in the storage unit based on the command signal output in the linked operation step. A video / audio data output step for outputting reproduction data obtained by reproducing the video / audio data based on the instruction signal output in the interlocking operation step, and a reproduction step for reproducing the reproduction data output in the video / audio data output step (Claim 13).
[0023]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
(A) Description of an embodiment of the present invention
FIG. 1 is a configuration diagram of a broadcast / distribution system according to an embodiment of the present invention. The broadcast / distribution system (hereinafter sometimes abbreviated as “system”) 24 shown in FIG. 1 broadcasts broadcast programs (hereinafter also referred to as “programs”) such as television programs and text broadcast programs. In addition to broadcasting / distributing using signal, cable distribution or Internet distribution, the program can be changed for the user based on the biological rhythm information. Here, the biological rhythm information is information relating to the living body such as physical condition such as back pain and stomach pain, and pulse. In other words, the system 24 allows the user to change the contents of the broadcast / distributed program according to the physical condition of the user.
[0024]
Here, in addition to the receiving device 25, the system 24 includes broadcast channels 30 and 31 and distribution channels 32 and 33. The broadcast channel 30 is a satellite channel and includes a broadcast station 20a, a BS (Broadcast Satellite) 21a, and an antenna 111a. The broadcast channel 31 is a terrestrial channel, and includes a broadcast station 20b, a radio tower 21b, and an antenna 111b. Become. Further, the distribution channel 32 is a cable television channel, and includes a CATV station 20c and an optical fiber 21c, and the distribution channel 33 is a channel via the Internet network, and includes a data distribution company 20d, an Internet network 26b, It consists of a telephone network 26a. These four types of broadcast channels and distribution channels are connected to the receiving device 25, respectively.
[0025]
First, the broadcast station 20a is a satellite wave broadcast station that transmits program data (program data signal) to the BS 21a using a frequency of several gigahertz. The BS 21a is a broadcasting satellite that transmits program data transmitted from the broadcasting station 20a toward the ground. The function of the BS 21a can also be realized using a communication satellite (CS). Furthermore, the antenna 111a is a receiving antenna. Thereby, for example, shooting data (shooting data signal) of a gymnastic program is converted into a broadcast wave signal and transmitted from the broadcast station 20a to the receiving device 25 via the BS 21a.
[0026]
The broadcast station 20b is a terrestrial broadcast station, and transmits program data to the radio tower 21b using a frequency of a VHF (Very High Frequency) band or a UHF (Ultra High Frequency) band. The radio tower 21b is a transmission station or a relay station that transmits program data transmitted from the broadcasting station 20b by terrestrial waves. Furthermore, the antenna 111b is a receiving antenna. Thereby, for example, shooting data of a golf lesson program is converted into a broadcast wave signal and transmitted from the broadcast station 20b to the receiving device 25 via the radio tower 21b.
[0027]
In this terrestrial system, television data (television signal) is transmitted by superimposing secondary information such as characters on the 21st horizontal section in the vertical blanking period as digital data. It has become. Specifically, as will be described later, the secondary information is included in a part of the 21st horizontal section in the vertical blanking period of the second field (the portion scanned in the second half when scanning one screen). It is designed to be superimposed. Further, the secondary information is auxiliary data attached to the television data, and is superimposed in order to execute an interlocking operation in association with biological information related to health.
[0028]
Therefore, a program suitable for the health condition of each user can be provided without changing the system format in the existing television broadcasting.
Further, the CATV station 20c is a broadcasting station that transmits a program, a movie work, a video work, etc. using an optical fiber 21c or a coaxial cable (not shown). Thereby, for example, shooting data of a cooking program is converted into an optical signal and transmitted to the receiving device 25 using the optical fiber 21c or the like.
[0029]
The data distribution company 20d is a company that distributes programs, movie works, video works, etc. to the receiving device 25 via the Internet network 26b defined by the Internet protocol and the telephone network 26a that provides mobile phone services. is there. As a result, for example, medical program shooting data is converted into Internet protocol data and a telephone line signal, and stored in a storage device 23 provided in the receiving device 25 for storing program data. Take out and use.
[0030]
In the following description, the transmitting side means the broadcasting stations 20a and 20b, the CATV station 20c, and the data distribution company 20d, and the receiving side means the server 1.
Further, in the present embodiment, it is possible to provide only one type of these reception channels without providing all the four types of reception channels shown in FIG.
Next, the receiving device 25 receives a program, generates sound of the program, and displays a video. The receiving device 25 includes a home server device (hereinafter sometimes abbreviated as a server) 1 and a biometric sensor. 130, a remote control device 131, a storage device 23, and a television receiver 2 are provided. Between these server 1, biosensor 130, remote control device 131, storage device 23, and television receiver 2, a connector or the like is provided. Is wired by.
[0031]
Here, the server 1 is for receiving program data from the BS 21a, the radio tower 21b, the CATV station 20c or the data distribution company 20d, and receives and demodulates broadcast wave signals, cable signals or telephone line signals. Then, for each user, biometric information relating to health is analyzed, and video / audio auxiliary data (image / audio auxiliary data) relating to the contents of the demodulated program is edited based on the biometric information. The video / audio auxiliary data includes both visual auxiliary data such as still images and moving images and auditory auxiliary data such as human voice, sound and music.
[0032]
The server 1 also has an antenna 111a for receiving a broadcast wave signal from the BS 21a and an antenna 111b for receiving a broadcast wave signal from the radio tower 21b, and distribution data from the CATV station 20c. And distribution data from the Internet 26a are input. The server 1 can process the input program data for the user.
[0033]
In addition, the biological sensor 130 detects and measures the biological information of the user. This biological information is related to health, for example, medical information about the body such as a pulse, a heart rate monitor, or the number of walks per day. The biosensor 130 functions as an acquisition unit that acquires health data corresponding to each scene included in the program, which is included in the auxiliary data (auxiliary signal). The biosensor 130 may be a portable pedometer to measure the number of walks.
[0034]
Further, the remote control device 131 is for inputting the user's biological information by the user's own hand. The remote control device 131 functions as an acquisition unit that acquires biological information together with the biological sensor 130.
In addition to inputting biometric information using the remote control device 131 and the biometric sensor 130, biometric information acquired at other locations can be input via, for example, the Internet network 26b or the telephone network 26a. In this way, biometric information acquired remotely can be used.
[0035]
The storage device 23 stores program data corresponding to four types of reception channels, and this function is realized by, for example, a hard disk and a RAM. The television receiver 2 reads program data stored in the storage device 23 by the server 1 and displays the contents of the program.
Thereby, the broadcast wave signal including the television data transmitted from the broadcast station 20a is received by the antenna 111a, and the channel of the received broadcast wave signal is selected by the tuner 112. For the selected channel, Television data is demodulated. The baseband signal obtained by this demodulation is defined by the NTSC system.
[0036]
In the NTSC system, the first field and the second field are each composed of 262.5 scanning lines, and one frame (one screen) is composed of these two types of fields. The transmitting side transmits 30 frames per second, and the receiving side (server 1) traces 60 times per minute.
[0037]
In addition, the screen scanning method of the server 1 traces the odd-numbered scanning lines (262 lines) from the top to the bottom of the screen during the first 1/60 seconds, and returns to the top. During the next 1/60 second, even-numbered scanning lines (262 lines) are traced from the top to the bottom of the screen. That is, one screen is alternately traced every 1/60 seconds. Here, the time required for scanning from the upper left to the lower right of the screen is called a vertical blanking period (hereinafter also referred to as VBI [Vertical Blanking Interval]), and is a period in which no information data is written. Have
[0038]
Also, using this vertical blanking period, the transmitting side transmits secondary information for assisting or supplementing the electronic program guide, the character multiplexed signal, and the contents of the program currently being broadcast. That is, a transmitter (not shown) provided on the transmission side multiplexes this secondary information as program data auxiliary data (auxiliary signal) into program data. In other words, the transmitter multiplexes the auxiliary data in the vertical blanking period of the television data. Then, the server 1 demodulates and extracts auxiliary data from the broadcast wave signal.
[0039]
As an example of teletext broadcasting, subtitle broadcasting called closed captioning adopted by US television broadcasting is widely known. The closed caption is a broadcast that multiplexes closed caption characters using auxiliary data.
Further, the broadcast channel 31 that broadcasts the terrestrial wave, with regard to the closed caption data format, 14-bit data excluding the parity bit is received in the 21st horizontal period of the VBI of the first field or the second field. It is supposed to be inserted. Here, both subtitles in two languages are transmitted using the first field, and are prepared for broadcasting subtitles written in the third language and the fourth language. The second field being used is rarely used.
[0040]
For this reason, the 21st horizontal period of the VBI of the second field (the 284th period when a serial number is assigned to the horizontal period of one frame) is used, and in addition to closed captions and text data in other languages. Various methods for adding various information have been proposed. This method is called an extended data service (hereinafter referred to as XDS), and several types of transmission contents have already been defined.
[0041]
FIG. 2 is a schematic block diagram of the server 1 according to an embodiment of the present invention. The server 1 shown in FIG. 2 includes antennas 111a and 111b, a tuner 112, a video / audio decoder (hereinafter also referred to as a decoder) 116, and a large-capacity storage search management unit (hereinafter referred to as a storage unit). ) 114, a reproduction unit 115, an interlocking unit 132, and a video / audio auxiliary signal editing unit (hereinafter also referred to as a data editing / output unit) 121.
[0042]
Here, the tuner 112 selects the frequency of the broadcast wave signal received by the antenna 111a or the antenna 111b, and demodulates the selected program data, and each of the CATV station 20c and the telephone network 26a. It also demodulates program data input via the network. The program data is demodulated and a baseband signal is output.
[0043]
Next, the video / audio decoder 116 demodulates content data having main data composed of a plurality of unit data related to video / audio and sub data including attribute information data assigned to each unit data, and the main data and sub data are demodulated. And has an NTSC decoder 113 and a VBI data decoder 120.
The NTSC decoder 113 demodulates the main data of the content data and outputs the main data. Specifically, the NTSC decoder 113 outputs video / audio data obtained by converting demodulated program data into a luminance signal and a color signal.
[0044]
Here, the content means a movie work, a video work, etc. in addition to a program. The main data is video / audio data, and the sub data is auxiliary data. In the present embodiment, the video / audio data includes a plurality of unit video / audio data. For example, as shown in FIG. 3A, the video / audio data includes a plurality of unit video / audio data (for example, a plurality of motion scenes such as “side bending” and “forward bending” in a gymnastic program). Each of the video and audio data can be given a set value such as time (seconds) as a unit scene. Also, “time”, “number of times”, “load”, etc. shown in FIG. 3A all mean attribute information data (program attribute information data) assigned to each of these unit video and audio data. . The attribute information data such as “time”, “number of times”, “load”, and the like are collectively sub-data.
[0045]
Further, the VBI data decoder 120 (see FIG. 2) decodes auxiliary data multiplexed in the vertical blanking period (VBI). The auxiliary data includes electronic program guides, character multiplexed signals, supplement data transmitted to supplement the current program, and health data corresponding to each scene constituting the program.
Therefore, the decoder 116 receives program data having video / audio data including a plurality of unit video / audio data corresponding to each scene in the program and auxiliary data including program attribute information data assigned to each unit video / audio data. It is configured to demodulate and output video / audio data and auxiliary data.
[0046]
Accordingly, the decoder 116 can obtain program data from a radio signal using the NTSC system, and the decoder 116 can also obtain program data from a wired system or a recording medium on which information data is recorded. To get from.
In this way, a large number of users can be acquired regardless of the type of broadcast / distribution method, and regardless of the installation location of the server 1 and the reception form.
[0047]
Hereinafter, the NTSC decoder 113 and the VBI data decoder 120 may be abbreviated as a decoder 113 and a decoder 120, respectively.
The accumulation unit 114 accumulates main data and sub data output from the decoder 116, and this function is realized by, for example, a hard disk or RAM. That is, the storage unit 114 stores the video / audio data and auxiliary data output from the decoder 116.
[0048]
Here, the auxiliary data is auxiliary data that is transmitted together with video, audio, and television data based on the television data in the scene name, time, and scene. In other words, auxiliary data is stored, searched, and managed by the storage unit 114.
Subsequently, the storage unit 114 is provided with a data editing / output unit 121. The data editing / output unit 121 edits the sub-data stored in the storage unit 114 based on an interlock operation instruction signal (instruction signal) output from the interlock unit 132 described below, and reproduces the main data. Data is output. Here, the instruction signal is associated with each of the auxiliary data and the biological information data related to health to instruct a linked operation. Specifically, the instruction signal relates to an increase or decrease in body load. That is, the data editing / output unit 121 edits the auxiliary data stored in the storage unit 114 based on the instruction signal output from the interlocking unit 132, and outputs reproduction data obtained by reproducing the video / audio data.
[0049]
The data editing / output unit 121 functions as a video / audio auxiliary signal editing unit. These functions are realized by cooperation of a central processing unit (CPU), a read only memory (ROM), a random access memory (RAM), an integrated circuit (IC), and the like.
Further, the playback unit 115 plays back the playback data output from the data editing / output unit 121. This function is also realized by cooperation of the CPU, ROM, RAM, and IC.
[0050]
Subsequently, the interlocking unit 132 outputs an instruction signal instructing the interlocking operation in association with the sub-data stored in the storage unit 114 and the biological information data related to health. That is, the interlocking unit 132 outputs an instruction signal instructing the interlocking operation associated with each of the auxiliary data stored in the storage unit 114 and the biological information data related to health. This function is realized by the cooperation of the CPU, ROM, RAM and IC.
[0051]
For example, as shown in FIG. 8, the interlocking unit 132 includes a biological state output unit 132a and an instruction output unit 132b. And the interlocking | linkage part 132 instruct | indicates the interlocking | linkage operation | movement which linked | related the health data and biometric information corresponding to each scene which comprises a program. Thereby, the interlocking unit 132 can cope with various interlocking modes. Details of this will be described later with reference to FIGS. 3 (a) and 3 (b).
[0052]
In addition, the interlocking unit 132 can receive two or more pieces of biological information data. Therefore, since editing is performed based on various biological information, accurate and fine editing is possible.
In addition, since what has the same code | symbol as what was shown in FIG. 2 and mentioned above has the same thing or the same function, further description is abbreviate | omitted.
[0053]
Thereby, the broadcast wave signal received via the antennas 111a and 111b and the program data input via the distribution channels 31 and 32 are input to the server 1, respectively. Then, the program data selected by the tuner 112 is demodulated, and the input program data is demodulated. The demodulated baseband signal is input to the NTSC decoder 113, decoded, and video / audio data converted into a luminance signal and a color signal is output. Further, data output from the tuner 112 is also input to the VBI data decoder 120, and auxiliary data is output.
[0054]
The video / audio data from the NTSC decoder 113 and the auxiliary data from the VBI data decoder 120 are both stored in the storage unit 114.
Here, among the outputs of the VBI data decoder 120, the health data corresponding to each scene constituting the program is sequentially input to the interlocking unit 132. In addition, the user's manual input from the remote control device 131 and the biological information from the biological sensor 130 are both input to the interlocking unit 132.
[0055]
On the other hand, for the user's biological information (physical condition such as back pain and stomach pain, biological rhythm such as pulse), the biological information of the user is detected and measured by the biological sensor 130, and the biological information of the user is detected by the remote control device 131. The user himself / herself manually inputs these biometric information to the server 1. Therefore, the interlocking unit 132 is configured to output information on physical condition and biological rhythm as an instruction signal.
[0056]
Then, in the server 1, the television data (for example, multiplex broadcasting) is re-edited so as to be suitable for the user's body by data processing based on the input biological information.
Specifically, the interlocking unit 132 uses a neural network based on a pre-weighted pack propagation method based on the biological information from the remote control device 131 and the biological information from the biological sensor 130 to determine the degree of user fatigue, etc. The biological state is obtained, and the biological state is sequentially compared with the health data corresponding to each scene constituting the program.
[0057]
Further, the interlock unit 132 sequentially generates instruction signals for shortening, extending and deleting the required time in each scene of the program, and changing the contents, and the instruction signals are generated by the data editing / output unit 121 and the reproduction unit. 115.
Next, the data editing / output unit 121 edits the sub data stored in the storage unit 114 based on the instruction signal. More specifically, the data editing / output unit 121 generates reproduction data in accordance with an instruction signal from the interlocking unit 132, and stores the corresponding program or the video / audio auxiliary data of this gymnastic program recorded last from the storage unit 114. The program is taken out, re-edited by the editing method sequentially transmitted, and recorded in the storage unit 114 as a new program.
[0058]
Then, the reproduction unit 115 sequentially takes out the video / audio data and auxiliary data corresponding to the newly edited new program (for example, a gymnastic program) by the storage unit 114 in accordance with the instruction signal from the interlocking unit 132. And played.
In this way, the broadcast program data is re-edited to a content suitable for each user and broadcast on the television receiver 2.
[0059]
Next, the server 1 of the present invention will be described by taking a gymnastic program as an example of a program related to health.
The server 1 of the present invention is a mode in which, in a program of a gymnastic program (such as “Radio Gymnastics”), the viewer sees the movement of the actor appearing in the program and performs the gymnastics in accordance with the movement is there. The procedure for reediting a gymnastic program will be specifically described below.
[0060]
The gymnastic program to be broadcast is transmitted by adding the scene name, time, the number of repetitions in the scene, and the load on the body as health data corresponding to each scene to the auxiliary data of the television data. In addition to the health data corresponding to each scene, the auxiliary data is transmitted in a state including electronic program guides, character multiplexed signals, and complementary data transmitted to complement the currently broadcast program.
[0061]
FIG. 3A is a diagram showing an example of auxiliary data according to an embodiment of the present invention, and the table 42 included in the auxiliary data shown in FIG. 3A shows health data of auxiliary data related to a gymnastic program. It is an example. Examples of each scene of the program include lateral bending, forward bending, jumping with limbs spread, upper arm extension, bicycle movement (lie down), and sitting forward bending forward. For each of these scenes, the time (seconds) that the scene lasts, the number of times the scene is repeated (times), and the magnitude of the physical load on the user are set. This auxiliary data is added to the transmission data by the transmission side that broadcasts and distributes.
[0062]
Next, a method for adding health data corresponding to each scene in the auxiliary data on the transmission side will be described.
The video / audio data generation method of the present invention has a period for transmitting main data composed of a plurality of unit data related to video / audio and a period for transmitting sub-data including attribute information data assigned to each unit data. This is a method for generating video and audio data. That is, the video / audio data generation method of the present invention uses the XDS transmission format (XDS format) to transmit health data corresponding to each scene.
[0063]
More specifically, first, the transmission side generates video / audio data including unit video / audio data corresponding to each scene in the program (generation step).
Next, the transmitting side superimposes auxiliary data including program attribute information data assigned to each scene on the video / audio data in the 21st horizontal section in the vertical blanking period (auxiliary data superimposing step).
[0064]
Then, the transmitting side transmits the video / audio data on which the auxiliary data is superimposed in the auxiliary data superimposing step (video / audio data transmitting step).
Thus, the user can arrange broadcast programs according to the user's physical condition at that time and day.
FIG. 3B shows a state after the processing by the interlocking unit 132, and the number of loads is changed, which will be described later.
[0065]
Then, program data is transmitted from the transmission side via the broadcast channels 30 and 31 or the distribution channels 32 and 33. This program data is transmitted as video and audio data together with control data based on the XDS format. The XDS format and the data insertion location will be described with reference to FIGS. 4 to 6A and 6B.
[0066]
FIG. 4 is a diagram showing an example of a transmission data waveform in the XDS format. The data waveform shown in FIG. 4 is a portion of data corresponding to the video / audio data, and is transmitted after being divided into a 1-byte first character (character 1) and a 1-byte second character (character 2). It has become so. The first character is an area in which an identification code for identifying the content of data written in the second character is written.
[0067]
FIG. 5 is a diagram showing the bit arrangement of the XDS format. The XDS format 39 shown in FIG. 5 has a first field 40 for the first character and a second field 41 for the second character. Then, the transmission side inserts health data (health data) corresponding to each scene into the fourth bit of the second field 41 when the first character is 01h to 04h (the color is changed). Darkened). Note that h represents a hexadecimal number.
[0068]
Here, the first field 40 is an area in which 16 types of identification codes (00h to 7Eh) are written. For example, 00h means NOP (No Operation), and 01h to 0Fh mean the start, continuation, and end of data in the XDS format, respectively. More specifically, 01h (start) means the start of information related to the currently broadcast program, 02h (control) means continuation of information related to the currently broadcast program, and 03h (start) indicates future broadcast. This means the start of information about the program to be played. In addition, 04h (control) means continuation of information relating to a program to be broadcast in the future, 05h (start) means start of information relating to the channel, and 0Fh (end) means end of data in the XDS format. . In addition, although each meaning of 06h-0Fh is prescribed | regulated, the description about the detail is abbreviate | omitted.
[0069]
Further, the second field 41 shown in FIG. 5 has a region that has already been defined and a region that has not yet been defined. Here, the seventh bit of the second field 41 is for parity, and the data is inserted into 3 bits of 0 to 2 and 4 bits of 3 to 6 of the second character. Yes. That is, the interval between the second bit and the third bit corresponds to the transmission information delimiter.
[0070]
Then, the transmission side inserts desired data into the darkened area of the second field 41 shown in FIG. Specifically, when the identification code of the first character is 01h, the undefined areas of the second character are 08h, 0Ah, 0Bh, 18h to 1Fh, 2xh, and 3xh to 7xh (x represents the down care). ). When the identification code of the first character is 05h, the contents to be written are defined for all of the second characters 01h to 03h, and the remaining codes are not defined.
[0071]
Therefore, the broadcast station 20b can insert desired data in an undefined area and transmit health data corresponding to each scene using a format other than the above-described example of the XDS format.
Further, since the health data corresponding to each program scene is transmitted as a part of the data in the XDS format, the transmission side can transmit the data using the existing format without using the already defined area.
[0072]
Next, a specific example of transmitting health data corresponding to each scene as a part of data in the XDS format will be described with reference to FIGS.
FIG. 6A is a diagram illustrating an example of a first character according to an embodiment of the present invention, and FIG. 6B is a diagram illustrating an example of a second character according to an embodiment of the present invention. Each of the eight types of first character and second character shown in FIGS. 6A and 6B has a time from the transmitting side at eight types of times (denoted as times 1 to 8). It was sent after shifting. Also, the two-dot chain line shown in FIGS. 6A and 6B corresponds to the bit delimiter of the second character shown in FIG.
[0073]
Then, the broadcasting station 20b inserts 01h at time 1 to signify the start of data, and inserts 0Fh at time 8 to signify the end of data. Health data corresponding to the scene is inserted.
More specifically, the broadcast station 20b inserts 01h (start: currently being broadcast) into the first character at time 1 and 40h, which is undefined data, into the second character. At times 2 to 7, the health data corresponding to each scene is written as “JUMP, 16, 8, 4”. These data contents represent the scene name, time, the number of repetitions in the scene, and the load on the body, respectively. In addition, the broadcast station 20b adds an end code and a checksum (checksum) each represented by 0Fh to indicate the end of the data at time 8.
[0074]
As a result, the server 1 receives and decodes and recognizes the 01h code, so that subsequent data is transmitted as health data (health data) corresponding to each scene using a variable-length character string. And knows the transmission of a character string such as “JUMP (jumping)”.
Thus, the interlocking unit 132 of the server 1 can process the subsequent data (first character and second character) as health data corresponding to each scene. That is, the interlocking unit 132 can output health data corresponding to each scene in units of variable-length frames, thereby allowing the user to freely edit the program.
[0075]
Next, transmission of closed caption data will be described with reference to FIG. This closed caption is an official teletext broadcast developed by a non-profit organization in the United States. The user can freely switch between displaying and hiding English subtitles on the TV screen using a dedicated decoder. Therefore, most of the lines and narrations are displayed on the TV screen as subtitles, so that people with hearing impairments can watch TV and videos, and English learning for people who use English as a second foreign language. Is also used.
[0076]
FIG. 7 is a diagram showing an example of a frame format according to an embodiment of the present invention. The transmission data (frames n−1 to n + i + 3) shown in FIG. 7 each have 16 bits, and the data is superimposed as additional information in the 21st horizontal period in the second field of each frame. ing. Note that n and i both represent natural numbers.
[0077]
Transmission data in the XDS format is inserted in the 21st horizontal period in the second field of each frame of frame n, frame n + 1, frame n + i + 1, frame n + i + 2, and frame n + i + 3 shown in FIG. .
Therefore, the auxiliary data superimposing step is configured so that the auxiliary data conforms to the format of the closed caption extended data service (XDS format). That is, the auxiliary data for executing the interlocking operation in association with the biometric information superimposed on the 21st horizontal section conforms to the XDS format.
[0078]
Thereby, the transmission side can provide a program suitable for the health condition of each user without changing any existing television broadcast system format. The program data from the transmission side is received by the server 1.
In FIG. 7, closed caption data is inserted into two consecutive frames from frame n-1, frame n + 2, and frame n + i. In the following description, the nth frame is referred to as frame n, and other frames may be similarly referred to as, for example, frame n + 1.
[0079]
Furthermore, the closed caption data is set to have priority over the XDS format data. Note that data in the XDS format is inserted in the 21st horizontal period of a frame in which closed caption data is not superimposed.
In this manner, closed caption data can be transmitted, and XDS format data can also be transmitted reliably.
[0080]
Next, program editing of a gymnastic program on the receiving side will be described.
In the XDS format shown in FIG. 4, the first character of the nth frame (frame n) is a code (any one of 01h to 0Eh) signifying the start of the XDS format. The format type code is written. For example, when the type code is “time information”, data included in each of frame n + 1 and frame n + i + 2 represents time.
[0081]
When the data in the XDS format is interrupted by the closed caption data, the first character of data indicating continuation is written in the frame n + i + 1. Then, the end code 0Fh is written in the frame n + i + 3. At this time, a checksum is written in the second character in order to detect an error in data in the XDS format.
[0082]
Therefore, on the transmission side, when the auxiliary data is superimposed (auxiliary data superimposing step), the auxiliary data is superimposed on the 21st horizontal section in the vertical blanking period of the second field (horizontal section superimposing step). Then, identification information indicating that the auxiliary data is associated with the biological information data is superimposed on the 21st horizontal section (identification information superimposing step). In other words, auxiliary data for executing the interlocking operation is superimposed, and identification data for distinguishing auxiliary data (auxiliary signal) for executing the interlocking operation associated with biological information from the subsidiary information is superimposed. Is done.
[0083]
In FIG. 2, the gymnastic program transmitted from the transmission side is demodulated by the tuner 112 of the server 1 and input to both the NTSC decoder 113 and the VBI data decoder 120. Subsequently, both the output of the NTSC decoder 113 and the output of the VBI data decoder 120 are accumulated in the accumulation unit 114, and this gymnastic program is accumulated. That is, the broadcasted program is a program related to health, and the decoder 116 outputs health data regarding scene names, time, the number of repetitions of unit scenes, and health data regarding physical load as auxiliary data corresponding to each scene in the program. It has become. In addition, among the outputs of the VBI data decoder 120, health data corresponding to each scene constituting the program is sequentially transmitted to the interlocking unit 132. The auxiliary data is multiplexed in the vertical blanking period (VBI).
[0084]
As a result, the auxiliary data and the biometric information are associated with each other in detail, so that editing and reproduction are further facilitated.
FIG. 8 is a block diagram of the interlocking unit 132 according to an embodiment of the present invention. The interlocking unit 132 shown in FIG. 8 includes a biological state output unit 132a and an instruction output unit 132b. Here, the biological state output unit 132a outputs biological state data related to the biological state based on the biological information data, and stores the biological information data and the biological state data in association with each other (first table). 43. The table 43 is realized by a hard disk or a ROM.
[0085]
FIG. 9 is a diagram showing an example of information recorded in the table 43 according to the embodiment of the present invention. The table 43 shown in FIG. 9 has two types of columns of “biological information”, “input source”, and “biological state”. The biometric information is information that may have some influence on the user's body, such as “back pain”, “played soccer”, “moderate fatigue”, “lack of sleep”. The input source is information for identifying inputs from the remote control device 131 and the biological sensor 130. Furthermore, the biological state is information representing a physical state such as “a degree of fatigue”, “a subjective symptom such as low back pain”, “a pulse”, and the like, which can be diagnosed medically.
[0086]
Using the remote control device 131, the user manually inputs biometric information such as “I have a back pain today” and “I played soccer yesterday”. Simultaneously with this input, medical data such as “pulse” by the biosensor 130 is input to the interlocking unit 132.
In the table 43 of the interlocking unit 132, the biometric information input from each of the biometric sensor 130 and the remote control device 131 is preliminarily obtained by a neural network based on a pack propagation method weighted corresponding to the input biometric information. The degree of physical fatigue of the user (the biological state in FIG. 9) is obtained. In this case, it is judged as moderate fatigue.
[0087]
Thus, the user can obtain the biological state by the table 43 that associates the biological information with the biological state based on the determination based on the information from the remote control device 131 and the information from the biological sensor 130.
Next, by using a table in which the biological state output from the table 43 is associated with the exercise menu of the optimum load for the user, the user can obtain an increase / decrease value of the load corresponding to the exercise content. Yes.
[0088]
Also, the instruction output unit 132b shown in FIG. 8 compares the biological state data with the health data and outputs an instruction signal, and includes a comparison unit 45 and a table (second table) 44. Has been.
Here, the comparison unit 45 compares the biological state data with the health data and outputs a comparison result, and this function is realized by a CPU, a ROM, a RAM, and the like. The table 44 accumulates increase / decrease values related to shortening, extending and deleting the required time in each scene, and changing the contents as instruction signals based on the comparison result, and is realized by a ROM or the like.
[0089]
FIG. 10 is a diagram showing an example of information recorded in the table 44 according to an embodiment of the present invention, and this table 44 is recorded in association with the biological state and gymnastics. The table 44 shown in FIG. 10 is provided with three types of a biological state, gymnastic content (gymnastic menu), and load reduction. The user can obtain a video editing method for each scene from the load increase / decrease value based on the recorded contents of the table 44. For example, when the user's “biological condition” is “back pain”, the interlocking unit 132 deletes “jumping exercises” from the contents of the exercises.
[0090]
In addition, the interlocking unit 132 is set in advance as an initial value so that the minimum number of repetitions of each exercise content is four. When the load increases by 1, the interlocking unit 132 inputs an instruction signal to each of the data editing / output unit 121 and the playback unit 115 to add video and audio corresponding to the minimum number of repetitions. . For example, when the user's biological state is fatigue-free, the interlocking unit 132 increases the image for the minimum number of repetitions once for the exercise of extending the limbs.
[0091]
On the other hand, when the load decreases by 1, the interlocking unit 132 inputs an instruction signal to the data editing / output unit 121 to reduce the video for the minimum number of repetitions. For example, in FIG. 10, when the user's biological condition is low back pain, the interlocking unit 132 reduces the image once by the minimum number of repetitions for the exercise that moves the limb greatly.
[0092]
When the video repeat count is less than or equal to the minimum repeat count, the interlocking unit 132 sets the video / audio playback time to be 20 times longer than the original playback time for each of the data editing / output unit 121 and the playback unit 115. In the case of deletion, an instruction signal not to use video is input.
FIG. 3B is a view for explaining data after the interlocking process according to the embodiment of the present invention. The table 42 ′ shown in FIG. 3B is a table after processing by the interlocking unit 132. That is, in FIG. 3B, the interlocking unit 132 applies load increase / decrease to the health data illustrated in FIG. 3A to obtain the new repetition count, editing method, and edited video time. Is shown. Here, since the health data corresponding to each scene is sequentially transmitted from the broadcasting station corresponding to the progress of the program scene, the editing method is also sequentially transmitted from the interlocking unit 132 to the data editing / output unit 121. The
[0093]
Note that 1.5 editing is to create a new scene having 50% (50%) of the time of the original scene. In addition, 0.5 editing means creating a new scene having 50% of the time of the original scene, and deleting means not using that scene.
In this way, the user can re-edit programs related to health. In other words, the user inputs information such as back pain and lack of sleep into the server 1 and the server 1 receives the multiplex broadcast from the multiplex broadcast so that the user's troubled part of the body is reduced. The program can be re-edited by accessing the memory in which the program is stored.
[0094]
In addition, in this way, each user can reflect his / her physical condition on the television screen he / she is viewing, and can perform individualized exercises for each user.
With the above configuration, the video / audio data editing method of the present invention will be described with reference to FIG. FIG. 11 is a flowchart for explaining a video / audio data editing method according to an embodiment of the present invention.
[0095]
The video / audio data editing method of the present invention has a period for transmitting main data composed of a plurality of unit data related to video / audio and a period for transmitting sub-data including attribute information data assigned to each unit data. Is.
First, in step A1 shown in FIG. 11, the decoder 116 of the server 1 includes video / audio data composed of unit video / audio data corresponding to each scene in the program, auxiliary data including program attribute information data assigned to each scene, and Is demodulated and video / audio data and auxiliary data are output (decoding step).
[0096]
Next, in step A2, the decoder 116 accumulates the video / audio data and auxiliary data output in the decoding step in the accumulation unit 114 for data accumulation (accumulation step).
In step A3, the interlocking unit 132 outputs an instruction signal instructing the interlocking operation in association with each of the auxiliary data stored in the storage unit 114 and the biological information data related to health (interlocking operation step).
[0097]
Further, in step A4, the data editing / output unit 121 edits the auxiliary data stored in the storage unit 114 based on the instruction signal output in the interlocking operation step. Specifically, the data editing / output unit 121 edits the video / audio data and auxiliary data stored in the storage unit 114 based on the instruction signal, and writes the edited data as reproduction data in the storage unit 114 (auxiliary data editing step). .
[0098]
Subsequently, in step A5, reproduction data obtained by reproducing the video / audio data based on the instruction signal output in the interlocking operation step is output (video / audio data output step).
In step A6, the reproduction unit 115 reproduces the reproduction data output in the video / audio data output step, and the video / audio is reproduced (reproduction step).
[0099]
In this way, the viewer can generate a gymnastic program corresponding to each user.
By the way, in addition to the gymnastics program, it can be implemented even when a cooking program is used. Here, even if the content of the program is changed, it can be implemented with the same configuration as the above configuration (see FIG. 2).
[0100]
In the video / audio data editing method of the present invention, first, the decoder 116 of the server 1 includes video / audio data composed of unit video / audio data corresponding to each scene in the program, and program attribute information data assigned to each scene. Program data having auxiliary data is demodulated and video / audio data and auxiliary data are output (decoding step).
Next, the decoder 116 accumulates the video / audio data and auxiliary data output in the decoding step in the accumulation unit 114 for data accumulation (accumulation step).
[0101]
In step A3, the interlocking unit 132 outputs an instruction signal instructing the interlocking operation in association with each of the auxiliary data stored in the storage unit 114 and the biological information data related to health (interlocking operation step). As a result, the user inputs information such as indigestion into the server 1.
Further, the data editing / output unit 121 edits the auxiliary data stored in the storage unit 114 based on the instruction signal output in the interlocking operation step (auxiliary data editing step). As a result, the server 1 deletes indigestible ingredients and cooking methods from the multiplex broadcast, re-edits the recipe to promote digestion, and displays it on the television screen of each user.
[0102]
Subsequently, in step A5, reproduction data of the video / audio data is output based on the instruction signal output in the interlocking operation step (video / audio data output step).
In step A6, the playback unit 115 plays back the playback data output in the video / audio data output step (playback step).
[0103]
Thus, the present invention can be implemented even for a cooking program.
Further, as described above, the program content is specialized for each user, and the service is significantly improved.
And, in this way, at each home, workplace, etc., even if there is no device that can notify the appropriate exercise prescription for the user, it becomes possible to notify the exercise prescription, and since the moving image is used, the user can Without getting bored, the device can be used for a long period of time.
[0104]
In this way, the utility value is improved for both users and broadcasting stations, convenience is obtained, and auxiliary data is used to change the system format used in existing television broadcasting. Without providing a desired service.
In this way, the user edits the video / audio auxiliary data based on the health data corresponding to each scene constituting the program included in the video / audio auxiliary data and the user's biological state from the analysis result of the biological information. be able to.
[0105]
Therefore, in this way, the user can easily view the video / audio auxiliary data edited in accordance with the biological state of the user at that time.
In addition, in this way, it is possible to perform related processing between auxiliary data included in the television data and biological information obtained from the biometric sensor, and edit / playback of video, audio and auxiliary data. Send data that is suitable for your health. For this reason, it is possible to edit and replay auxiliary data multiplexed in related processing, video, audio and vertical blanking periods, and to re-edit and replay programs suitable for the health status of each user, Thereby, a high utility value can be obtained for both the user and the broadcasting station.
[0106]
(B) Other
The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.
The broadcasting system can be implemented using the PAL system, the SECAM system, the digital system, and the analog system in addition to the NTSC system.
[0107]
In addition to the 00h to 0Fh, the identification code of the first character shown in FIG. 5 is written with a control code for controlling the closed caption and the size and color of the text data, and a standard character. Detailed description thereof will be omitted.
The items of the number of times, biological information, and biological state are examples. For example, the minimum number of repetitions for each gymnastic content shown in FIG. 10 is not limited to 4, and can be variously changed according to the design policy. Various changes can be made according to the design policy. Furthermore, the items in the drawings are merely examples, and the superiority of the present invention is not impaired at all by adding, changing, or deleting items different from these.
[0108]
【The invention's effect】
As described above in detail, according to the home server device of the present invention, content data having main data composed of a plurality of unit data related to video and audio and sub data including attribute information data assigned to each unit data is obtained. A decoding unit that demodulates and outputs main data and sub-data, a storage unit that stores main data and sub-data output from the decoding unit, sub-data stored in the storage unit, and biological information data related to health Are linked to each other and output an instruction signal for instructing an interlocking operation, and the sub-data stored in the accumulating part is edited based on the instruction signal output by the interlocking part, and the main data is reproduced. Since it is configured with a data editing / output unit that outputs data, health data corresponding to each scene making up the program included in the auxiliary data Using, by the user's biological condition from the analysis result of the biological information, it is possible to edit video and audio auxiliary data. Therefore, the user can easily view the video / audio auxiliary data edited in accordance with the biological state of the user at that time (claim 1).
[0109]
Also, according to the home server device of the present invention, auxiliary data including video / audio data composed of a plurality of unit video / audio data corresponding to each scene in the program and program attribute information data assigned to each of the unit video / audio data. A decoding unit that demodulates program data having the above and outputs video / audio data and auxiliary data, a storage unit that stores video / audio data and auxiliary data output from the decoding unit, and an auxiliary unit stored in the storage unit While editing the auxiliary data accumulated in the accumulating unit based on the instruction signal output by the interlocking unit, the interlocking unit outputting the instruction signal instructing the interlocking operation associated with each of the data and the biological information data on health, Since it is configured with a data editing / output unit that outputs playback data that has played back audio and video data, the user can Can re-edit the program as motion-intensive for upset part of the body is reduced (claim 2).
[0110]
Furthermore, a playback unit that plays back the playback data output from the data editing / output unit may be provided, and in this way, each user can be displayed on the television screen that they are viewing. Individualized exercises can be executed for each user (claim 3).
The program is a program related to health, and the decoding unit is configured to output the health data regarding the scene name, time, the number of repetitions of the unit scene and the physical load corresponding to each scene in the program as auxiliary data. In this way, the auxiliary data and the biological information are associated with each other in detail, so that the editing / playback is further facilitated (claim 4).
[0111]
In addition, the interlocking unit may be configured to output information on physical condition and biological rhythm as an instruction signal (Claim 5), and in this way, the interlocking unit has each variable length frame as a unit. Since the health data corresponding to the scene can be output, the user can freely edit the program.
Furthermore, a biological state output unit that outputs biological state data related to the biological state based on the biological information data, and an instruction output unit that compares the biological state data with health data and outputs an instruction signal are provided. In this way, the user can take out and use the program at a desired opportunity (claims 6 to 8).
[0112]
Furthermore, the interlocking unit can be configured to receive a plurality of pieces of biological information data. In this way, editing is performed based on various types of biological information, so that accurate and detailed editing is possible. (Claim 9).
The decoding unit may be configured to obtain the program data from a wireless signal, or may be obtained from a wired system or a recording medium on which information data is recorded. In addition, a large number of users can be acquired regardless of the installation location and the reception form (claims 10, 11).
[0113]
In addition, according to the video / audio data editing method of the present invention, the decoding step of demodulating the content data having the main data and the sub data and outputting the main data and the sub data, and the main data and the sub data are performed. An accumulation step for accumulating in the accumulation unit for data accumulation, an associated operation step for outputting an instruction signal instructing an associated operation associated with each of the sub data and the biological information data, and editing the sub data based on the instruction signal Sub data editing step, a data editing / output step for outputting reproduction data obtained by reproducing the main data based on the instruction signal, and a reproduction step for reproducing the main data. Performs related processing of included auxiliary data and biological information obtained from biological sensors, and edits and reproduces video, audio and auxiliary data. It can, it is possible to transmit the data to suit the health status of each user (claim 12).
[0114]
According to the video / audio data editing method of the present invention, the decoding step for demodulating the program data including the video / audio data and the auxiliary data, and outputting the video / audio data and the auxiliary data, the video / audio data and the auxiliary data are performed. An interlocking operation that outputs an instruction signal instructing an interlocking operation associated with each of an accumulation step for accumulating data in an accumulating unit for data accumulation, auxiliary data accumulated in the accumulating unit, and biological information data related to health An auxiliary data editing step for editing auxiliary data stored in the storage unit based on the instruction signal, a video / audio data output step for outputting reproduction data obtained by reproducing the video / audio data based on the instruction signal, and reproduction data The viewer has a gymnastic program that corresponds to each user. Can be generated (claim 13).
[0115]
Furthermore, the video / audio data generation method of the present invention includes a generation step of generating video / audio data composed of unit video / audio data corresponding to each scene in a program, and program attribute information data assigned to each scene. An auxiliary data superimposing step for superimposing auxiliary data on video / audio data in a predetermined horizontal section in a vertical blanking period, and a video / audio data transmitting step for transmitting video / audio data on which auxiliary data is superimposed are configured. So, for example, most of the dialogue and narration are displayed on the TV screen, so that people with hearing impairments can watch TV and videos, and English of people who use English as a second foreign language. It is also used for learning (claim 14).
[0116]
In addition, the auxiliary data superimposing step includes a horizontal section superimposing step of superimposing the auxiliary data on a predetermined horizontal section in the vertical blanking period of the second field, and an identification indicating that the auxiliary data is associated with the biological information data. And an identification information superimposing step for superimposing information on a predetermined horizontal section. In this way, for example, the health of each user can be maintained without changing the system format in the existing television broadcasting. A program suitable for the state can be provided (claims 15 and 16).
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a broadcast / distribution system according to an embodiment of the present invention.
FIG. 2 is a schematic block diagram of a server according to an embodiment of the present invention.
3A is a diagram illustrating an example of auxiliary data according to an embodiment of the present invention, and FIG. 3B is a diagram for explaining data after interlocking processing according to an embodiment of the present invention. is there.
FIG. 4 is a diagram illustrating an example of a transmission data waveform in an XDS format.
FIG. 5 is a diagram illustrating a bit arrangement of an XDS format.
6A is a diagram illustrating an example of a first character according to an embodiment of the present invention, and FIG. 6B is a diagram illustrating an example of a second character according to an embodiment of the present invention.
FIG. 7 is a diagram illustrating an example of a frame format according to an embodiment of the present invention.
FIG. 8 is a block diagram of an interlocking unit according to an embodiment of the present invention.
FIG. 9 is a diagram showing an example of information recorded in a table associating a biological state and gymnastics according to an embodiment of the present invention.
FIG. 10 is a diagram showing an example of information recorded in a table according to an embodiment of the present invention.
FIG. 11 is a flowchart for explaining a video / audio data editing method according to an embodiment of the present invention;
[Explanation of symbols]
1 Home server device
2 Television receiver
20a, 20b broadcasting station
20c CATV station
20d data distribution company
21a BS
21b radio tower
21c optical fiber
23 Storage device
24 Broadcasting and distribution system
25 Receiver
26a telephone network
26b Internet network
30, 31 broadcast channel
32,33 delivery channels
39 XDS format
40 First field
41 Second field
42, 42 ', 43, 44 Table
45 Comparison part
111a, 111b antenna
112 tuner
113 NTSC decoder
114 Storage unit (large-capacity storage search management unit)
115 Playback unit
116 Video / Audio Decoder
120 VBI data decoder
121 Data editing / output unit (video / audio auxiliary signal editing unit)
130 Biosensor
131 Remote control device
132 Interlocking part
132a first memory
132b Second memory

Claims (13)

A decoding unit that demodulates content data having main data composed of a plurality of unit data related to video and audio and sub data including attribute information data assigned to each of the unit data, and outputs the main data and the sub data When,
An accumulation unit for accumulating the main data and the sub data output from the decoding unit;
An interlocking unit that outputs an instruction signal instructing an interlocking operation associated with each of the sub-data stored in the storing unit and the biological information data relating to health;
The sub-data stored in the storage unit is edited based on the instruction signal output from the interlocking unit, and a data editing / output unit that outputs reproduction data obtained by reproducing the main data is provided. A home server device. Demodulating program data having video and audio data composed of a plurality of unit video and audio data corresponding to each scene in the program, and at least auxiliary data including program attribute information data assigned to each of the unit video and audio data, A decoding unit for outputting video / audio data and the auxiliary data;
A storage unit for storing the video / audio data and the auxiliary data output from the decoding unit;
An interlocking unit that outputs an instruction signal instructing an interlocking operation associated with each of the auxiliary data stored in the storage unit and the biological information data related to health;
The auxiliary data stored in the storage unit is edited based on the instruction signal output by the interlocking unit, and a data editing / output unit that outputs reproduction data obtained by reproducing the video / audio data is provided. A home server device characterized by that. 3. The home server device according to claim 1, further comprising a reproduction unit that reproduces the reproduction data output from the data editing / output unit. The program is a program about health,
The decoding unit is configured to output at least scene name, time, the number of repetitions of a unit scene, and health data relating to physical load corresponding to each scene in the program as the auxiliary data. The home server device according to claim 2. The interlocking part is
5. The home server device according to claim 4, wherein the home server device is configured to output at least information on physical condition and biological rhythm as the instruction signal. The interlocking part is
A biological state output unit that outputs biological state data related to the biological state based on the biological information data;
5. The home server device according to claim 4, further comprising an instruction output unit that compares the biological state data with the health data and outputs the instruction signal. The biological state output unit
7. The home server device according to claim 6, comprising a first table for storing the biological information data and the biological state data in association with each other. The instruction output unit
A comparison unit that compares the biological state data with the health data and outputs a comparison result;
Based on the comparison result, it is characterized by comprising a second table that accumulates as an instruction signal an increase / decrease value relating to shortening, extending and deleting the required time in each scene, and changing the contents, The home server device according to claim 7. The interlocking part is
3. The home server device according to claim 2, wherein a plurality of pieces of biological information data are inputted. The decoding unit
3. The home server apparatus according to claim 2, wherein the program data is obtained from a radio signal using a predetermined method. The decoding unit
3. The home server device according to claim 2, wherein the program data is obtained from at least one of a wired system or a recording medium on which information data is recorded. A method for editing video and audio data, comprising: a period for transmitting main data comprising a plurality of unit data related to video and audio; and a period for transmitting sub data including attribute information data assigned to each of the unit data,
A decoding step of demodulating content data having main data composed of a plurality of unit data related to video and audio and sub data including attribute information data assigned to each of the unit data, and outputting the main data and the sub data When,
An accumulation step for accumulating the main data and the sub data output in the decoding step in an accumulation unit for data accumulation;
An interlocking operation step of outputting an instruction signal instructing an interlocking operation associated with each of the sub-data stored in the storage unit and the biological information data relating to health;
A sub-data editing step for editing the sub-data stored in the storage unit based on the instruction signal output in the interlocking operation step;
A data editing / output step for outputting reproduction data obtained by reproducing the main data stored in the storage unit based on the instruction signal output in the interlock operation step;
A video / audio data editing method, comprising: a reproduction step of reproducing the reproduction data output in the data editing / output step. A period for transmitting video / audio data composed of a plurality of unit video / audio data corresponding to each scene in the program, and a period for transmitting auxiliary data including at least program attribute information data assigned to each of the unit video / audio data. A method for editing video and audio data, comprising:
Program data having video / audio data composed of unit video / audio data corresponding to each scene in the program and auxiliary data including at least program attribute information data assigned to each scene is demodulated, and the video / audio data and the auxiliary data are demodulated. A decoding step for outputting data;
An accumulation step for accumulating the video / audio data and the auxiliary data output in the decoding step in an accumulation unit for data accumulation;
An interlocking operation step of outputting an instruction signal instructing an interlocking operation, associated with each of the auxiliary data stored in the storage unit and the biological information data related to health;
An auxiliary data editing step of editing the auxiliary data stored in the storage unit based on the instruction signal output in the interlocking operation step;
A video / audio data output step of outputting reproduction data obtained by reproducing the video / audio data based on the instruction signal output in the interlock operation step;
A video / audio data editing method comprising: a reproduction step of reproducing the reproduction data output in the video / audio data output step .

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