JP2009004082A - Information processing device, information processing method and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To satisfactorily attain the storage of received data when GUI data including lyric data are received. <P>SOLUTION: The GUI data associated with audio data and containing at least lyric data are received. Display data generated based on the received GUI data are displayed. When the audio data are reproduced, the lyric data associated with the received audio data are displayed in synchronization with the reproduction of the audio data. The lyric data associated with the audio data selected based on the display data are stored. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

The present invention relates to an information processing apparatus, an information processing method, and a program suitable for application to a process of receiving a digital satellite broadcast, for example, and downloading the received music program to a recording device.

  Digital satellite broadcasting is spreading. Digital satellite broadcasting is more resistant to noise and fading than existing analog broadcasting, and can transmit high-quality signals. In addition, the frequency utilization efficiency is improved and the number of channels can be increased. For example, in digital satellite broadcasting, it is possible to secure several hundred channels with one satellite. In such digital satellite broadcasting, a large number of specialized channels for sports, movies, music, news, etc. are prepared, and programs for dedicated content are broadcast on these dedicated channels.

  Among these dedicated channels, the music channel is one of the popular channels, and promotional programs mainly introducing new songs and hit songs are broadcast.

  As described above, in the conventional music channel, new song introductions and hit song programs are sent by moving images and sounds. When viewers watch a music channel like this and find a song they like, they may want to purchase a CD of the song being introduced and enjoy it. You may also want to know information about the artist of the song and information about the album that contains the song. If you are watching a music program and want to know information about the artist of the song or the album that contains the song, you can get that information on the spot, and if you find a song you like, It would be very convenient if you could download the audio data. However, in the conventional music channel, the moving image and the sound related to the music are unilaterally transmitted, and such a request cannot be met.

  Therefore, in order to solve such problems, music content distribution in which information related to music broadcast on a music channel can be easily obtained and the music data can be easily downloaded to a data storage device. A system has been proposed (1997 patent application No. 308488). In such a music content distribution system, it has been proposed that the lyrics data and jacket data (still image data) can be downloaded together with the music data.

  By the way, when such a music content distribution system is assembled, a user receiving digital satellite broadcast uses a tuner for receiving digital satellite broadcast as a data storage device (recording device) using a storage medium such as a magneto-optical disk. ) To download the music program received by the tuner to the recording device. Here, when considering a process in which a user receives music downloaded using such a distribution system and downloads it to a recording device, the time when the user wants to record the music is broadcast (distributed), If it is determined by some method and the download process to the recording device is performed immediately before the determined broadcast time, the music desired by the user can be downloaded. However, in such a system, it is possible to transmit an enormous number (music number) of music data. For example, simply displaying a list of broadcast times for each music on a program guide screen or the like, It takes a lot of time and effort to find the desired music.

An object of the present invention is to facilitate the process of obtaining desired data on the receiving side when a large amount of data is distributed.

The present invention receives GUI data related to audio data, at least including lyric data,
Display the display data created based on the GUI data, and display the lyrics data related to the audio data received in synchronization with the reproduction of the audio data when the audio data is being reproduced;
The lyric data related to the audio data selected based on the display data is stored.

According to the present invention, the lyrics data related to the audio data selected based on the display data can be stored.

  Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

  The system to which the present invention is applied broadcasts a music program using digital satellite broadcasting, distributes audio data associated with the music program, thereby enabling a viewer to view the music program, When there is a song that you like to watch, you can easily purchase it on the spot.

  FIG. 1 shows the overall configuration of a music content distribution system to which the present invention is applied. As shown in this figure, the digital satellite broadcast ground station 1 has a TV program broadcast material from the TV program material server 6, a music data material from the music material server 7, and an audio additional information server 8. Audio additional information and GUI data from a GUI (Graphical User Interface) data server 9 are sent.

  The television program server 6 is a server that provides materials for ordinary music broadcast programs. The music broadcast material sent from the TV program material server 6 is a video and audio, and in a normal music broadcast program, for example, a video and audio for promoting a new song is broadcast, or the latest hit song is recorded. A countdown is broadcast.

  The music material server 7 is a server that provides an audio program using an audio channel. The audio program material is only audio. The music material server 7 sends audio program materials of a plurality of audio channels to the ground station 1. In the program broadcast of each audio channel, the same music is repeatedly broadcast for a predetermined unit time. Each audio channel is independent, and there are various ways of using it. For example, on one audio channel, the recommended song in the latest Japanese pop is broadcast repeatedly for a predetermined time, and on the other audio channel, the recommended song in the latest American pop is repeatedly broadcast for a predetermined time. On other audio channels, a recommended song from jazz may be broadcast repeatedly for a predetermined time. Further, a plurality of music pieces of the same artist may be divided into respective audio channels and repeatedly broadcast.

  The audio additional information server 8 provides attached information such as time information of music output from the music material server 7. Here, copyright information for each song, that is, information related to digital copy restrictions is also provided.

  The GUI data server 9 displays data for forming a screen for a list page of music to be distributed and an information page for each music, data for forming still image data for a jacket, and a screen for an EPG (Electric Program Guide). Data and the like for forming are provided. As will be described in detail later, in the system to which this example is applied, the lyrics of the music to be distributed, the concert information of the artist, and the like can be displayed on the screen by operating the GUI on the screen. In addition, music can be selected, downloaded, reserved, and the like by operating the GUI on the screen. The GUI data server 9 sends data for that purpose. Note that the GUI data in this example is data in a format defined by, for example, the MHEG (Multimedia and Hypermedia Information Coding Experts Group) method. In addition, for the still image data of the jacket and the text data of the lyrics, copyright information, that is, information relating to digital copy restrictions is attached to each data and sent.

  The ground station 1 receives the video data and audio data as the material of the music program broadcast from the TV program material server 6, the audio data as the material of the audio channel from the music material server 7, and the audio additional information server. The voice additional information and the GUI data from the GUI data server 9 are multiplexed and transmitted. At this time, video data of the TV program broadcast is compressed by, for example, MPEG (Moving Picture Experts Group) 2 system, and audio data of the TV program broadcast is compressed by the MPEG 2 audio system. The audio data of each audio channel is compressed by two different methods, for example, MPEG2 audio method and ATRAC (Adaptive Transform Acoustic Coding) method. These data are encrypted using the key information from the key information server 10 when multiplexing.

  A signal from the ground station 1 is received by the receiving equipment 3 installed in each home via the artificial satellite 2. The satellite 2 is equipped with a plurality of transponders. One transponder has a transmission capacity of 30 Mbps, for example. A parabolic antenna 11, an IRD (Integrated Receiver Decoder) 12, a storage device 13, and a television receiver 14 are prepared as the receiving equipment 3 in each home.

  A parabola antenna 11 receives a signal transmitted via the satellite 2. This received signal is converted to a predetermined frequency by an LNB (Low Noise Block Downconverter) 15 attached to the parabolic antenna 11 and supplied to the IRD 12.

  The IRD 12 selects a signal of a predetermined channel from the received signal and demodulates video data and audio data. The IRD 12 forms a list page of music to be distributed, an information page for each music, and a GUI screen. The output of the IRD 12 is supplied to the television receiver 14.

  The storage device 13 is for holding downloaded audio data. For example, as the storage device 13, an MD recorder / player using a magneto-optical disk called MD (mini disk) as a recording medium, a DAT recorder / player using a magnetic tape as a recording medium, an optical disk for video recording, etc. Can be used as a DVD recorder / player. It is also possible to use a personal computer as the storage device 13 and store audio data on the hard disk or CD-R.

  The IRD 12 is connected to the accounting server 5 via the telephone line 4, for example. An IC card in which various information is stored is inserted into the IRD 12. When the music audio data is downloaded, the information is stored in the IC card. This IC card information is sent to the accounting server 5 via the telephone line 4. The billing server 5 charges appropriately from this download information and charges the viewer. In this way, the copyright of the music to be downloaded can be protected by performing appropriate charging.

  In this way, in the system of this example, the ground station 1 has the video data and audio data as the material of the music program broadcast from the TV program material server 6 and the audio data as the material of the audio channel from the music material server 7 The voice additional information data from the voice additional information server 8 and the GUI data from the GUI data server 9 are multiplexed and transmitted. When this broadcast is received by the receiving equipment 3 at each home, a music program can be viewed and a GUI screen is displayed based on the sent GUI data. When a necessary operation is performed while viewing this GUI screen, an information page for each song can be viewed, and a trial listening for each song can be performed. Furthermore, by performing necessary operations while viewing the GUI screen, the audio data of the desired music can be downloaded and stored in the storage disk 13.

  Next, the viewer's operation at the receiving facility 3 installed in each home will be described in more detail.

  When this broadcast is received by the receiving equipment 3 at each home, a screen as shown in FIG. 2 is displayed on the television receiver 14. In the television program display area 21A at the upper left of the screen, a moving image based on the music program provided from the television program material server 6 is displayed. In the upper right part of the screen, a list 21B of music of each channel broadcast on the audio channel is displayed. A text display area 21C and a jacket display area 21D are set at the lower left of the screen. Further, a lyrics display button 22, a profile display button 23, an information display button 24, a reserved recording button 25, a reserved list display button 26, a recording history display button 27, and a download button 28 are displayed on the right side of the screen.

  The viewer searches for a song of interest while watching the song name displayed in the list 21B. When a musical piece of interest is found, the arrow key of the remote commander is operated to move the cursor to the musical piece, and then the remote commander enter key attached to the IRD 12 is pressed. As a result, it is possible to listen to the music with the cursor. That is, in each audio channel, since the same music is repeatedly broadcasted for a predetermined unit time, the screen of the TV program display area 21A is left as it is, and the audio channel of the music is switched to listen to the music. Can do. At this time, a still image of the MD jacket of the music is displayed in the jacket display area 21D.

  In this state, when the cursor is moved to the lyrics display button 22 and the enter key is pressed (hereinafter, the cursor is moved to the button and the operation of pressing the enter key is referred to as pressing the button), the lyrics of the music are displayed as audio data in the text display area 21C. Displayed at the synchronized timing. Similarly, when the profile display button 23 or the information display button 24 is pressed, the artist's profile or concert information corresponding to the music is displayed in the text display area 21C. Thus, the user can know what kind of music is currently distributed, and can know detailed information about each music.

  When the user wants to purchase the music that the user listens to, the download button 28 is pressed. When the download button 28 is pressed, the audio data of the selected music is downloaded and stored in the storage device 13. Along with the audio data of the music, the lyrics data, artist profile information, jacket still image data, and the like can also be downloaded. Each time a song is downloaded, the information is stored in the IC card in the IRD 12. The information stored in the IC card is taken up by the billing server 5 once a month, for example. As a result, the copyright of the downloaded music can be protected.

  In addition, the viewer presses the reservation recording button 25 to make a reservation for download in advance. When this button is pressed, the GUI screen is switched and a list of songs that can be reserved is displayed on the entire screen. This list can display the music searched in units of 1 hour, 1 week, genre, and the like. When the viewer selects a song for which a download reservation is to be made from this list, the information is registered in the IRD 12. If it is desired to confirm a song that has already been reserved for download, it can be displayed on the entire screen by pressing the reserved list display button 26. The music reserved in this way is downloaded by the IRD 12 at the reserved time and stored in the storage device 13.

  When the viewer wants to confirm the downloaded music, the viewer can press the recording history button 27 to display a list of already downloaded music on the entire screen.

  As described above, in the reception facility 3 of the system of this example, a list of music is displayed on the GUI screen of the television receiver 14. When a song is selected according to the display on the GUI screen, the song can be auditioned, and the lyrics of the song, the artist's profile, and the like can be known. Furthermore, it is possible to download music and reserve it, display a download history, a reserved music list, and the like.

  As described above, in the music content distribution system to which the present invention is applied, a music broadcast program is distributed and audio data of music is distributed using a plurality of audio channels. Then, it is possible to search for a desired music using a list of delivered music and the like and easily store the audio data in the storage device 13. Hereinafter, such a system will be described in more detail.

  FIG. 3 shows the configuration of the ground station 1 in the music content distribution system of this example.

  In FIG. 3, material data from the TV program material registration system 31 is registered in the AV server 35. This material data is video data and audio data. The data registered in the AV server 35 is sent to the television program transmission system 39, where the video data is compressed by, for example, the MPEG2 system, and the audio data is compressed by, for example, the MPEG2 audio system and packetized. The output of the television program transmission system 39 is sent to the multiplexer 44.

  The audio data from the music material registration system 32 is supplied to the MPEG2 audio encoder 36A and the ATRAC encoder 36B, encoded, and then registered in the MPEG audio server 40A and the ATRAC audio server 40B. The MPEG audio data registered in the MPEG audio server 40A is sent to the MPEG audio sending system 43A, where it is packetized and sent to the multiplexer 44. The ATRAC data registered in the ATRAC audio server 40B is sent to the ATRAC audio transmission system 43B as quadruple speed ATRAC data, packetized here, and then sent to the multiplexer 44.

  Further, the voice additional information from the voice additional information registration system 33 is registered in the voice additional information database 37. The voice additional information registered in the voice additional information database 37 is sent to the voice additional information transmission system 41, packetized here, and sent to the multiplexer 44.

  In addition, GUI data from the GUI material registration system 34 is registered in the GUI material database 38. The GUI material data registered in the GUI material database 38 is sent to the GUI authoring system 42, where the GUI screen data is processed and packetized, and then sent to the multiplexer 44. Here, the GUI material data includes still image information of the jacket, lyrics information of the music, concert information of the artist, etc. The still image information is, for example, 640 × 480 pixels compressed by JPEG (Joint Photographic Experts Group) method. The lyric information is, for example, text data within 800 characters and packetized.

  In the multiplexer 44, the video packet and the audio packet from the television program transmission system 39, the audio packet from the MPEG audio transmission system 43A, the quadruple speed audio packet from the ATRAC audio transmission system 43B, and the audio additional information transmission system 41 are transmitted. The voice additional information packet and the GUI data packet from the GUI authoring system 42 are time-axis multiplexed and encrypted using the key information from the key information server 10 (FIG. 1).

  The output of the multiplexer 44 is sent to a radio wave transmission system 45, where processing such as addition of an error correction code, modulation, and frequency conversion is performed, and then transmitted from the antenna to the satellite 2.

  FIG. 4 shows an example of data transmitted from the ground station 1. Each data shown in this figure is actually time-axis multiplexed. As shown in FIG. 4, the period from time t1 to time t2 is one event, and the next event is from time t2. An event is a unit for changing the lineup of music, and is usually in units of 30 minutes or 1 hour. For example, it may be possible to broadcast 20th to 11th of the top 20 of the latest hit songs at the previous event and broadcast 10th to 1st at the later event.

  As shown in FIG. 4, in the event from the time t1 to the time t2, a music program having a predetermined content A1 is broadcast by a normal video program broadcast. In an event starting from time t2, a music program having a predetermined content A2 is broadcast. This normal music program is broadcasted with moving images and audio.

  For example, 10 channels of channels CH1 to CH10 are prepared as audio channels. At this time, in each audio channel CH1, CH2, CH3,..., CH10, the same music is repeatedly transmitted during one event. That is, in the event from the time t1 to the time t2, the music B1 is repeatedly transmitted on the audio channel CH1, the music C1 is repeatedly transmitted on the audio channel CH2, and similarly, the music K1 is repeatedly transmitted on the audio channel CH10. Is done. In the event starting from time t2, the music B2 is repeatedly transmitted on the audio channel CH1, the music C2 is repeatedly transmitted on the audio channel CH2, and the music K2 is repeatedly transmitted similarly on the audio channel CH10. This is common to MPEG audio channels and 4x ATRAC audio channels.

  That is, in FIG. 4, the same numbers in (), which are channel programs of MPEG audio channels and quadruple speed ATRAC audio channels, relate to the same music. The numbers in parentheses () that are channel programs of audio additional information are additional audio information added to audio data having the same channel program. Furthermore, still image data and text data transmitted as GUI data are also formed for each channel. These data are time-division multiplexed in the transport packet of MPEG2 as shown in FIGS. 5A to 5D and transmitted in the IRD 12 as shown in FIGS. 5E to 5H. Reconstructed using the header information of each data packet.

  Here, FIG. 6 shows a conceptual diagram of the transport stream itself to be transmitted. As shown in this figure, the transport stream is a set of transport packets (TS packets) having a fixed length of 188 bytes. A TS packet includes a header, an adaptation field, and a payload. Data such as audio data, still image data, and audio additional information is stored in the payload. A packet ID (hereinafter referred to as PID) for distinguishing each stream or section is stored in the header.

  Data such as audio data, video data, and audio additional information transmitted in such a transport stream is transmitted in a content description format called MHEG-5. Here, the script data for instructing the display procedure of the GUI screen as shown in FIG. 2 is also transmitted as the contents of MHEG-5. FIG. 7 is a diagram showing the concept of data transmission in the MHEG format in this example, and the data broadcasting services here are all included in the route directory named service gateway. The objects included in the service gateway include types such as directories, files, streams, and stream events. These files are individual data files such as audio data, still image data, and text data. The stream includes information that links to other data services and AV streams. The stream event includes link information and time information. included. A directory is a folder for collecting data related to each other. These data are composed of a set of several modules and transmitted.

  The module is divided into blocks in predetermined units, and each block is given a header and converted into a format called DBB (Download Data Block). On the other hand, a control message called DII (Download Inform Indication) having information on the size of the module necessary for receiving the module on the receiving side and the location of the data service root directory on the receiving side A control message called DSI (Download Server Initiate) having information is created. These three types of messages, DBB, DII, and DSI, are periodically and repeatedly transmitted and transmitted in a ring structure called a carousel as shown in FIG. 7, so that the receiving side can receive them at any time.

  Next, the receiving equipment 3 in each home will be described.

  As shown in FIG. 1, a parabolic antenna 11, an IRD 12, a storage device 13, and a television receiver 14 are prepared as reception facilities in each home. Here, as shown in FIG. 8, a recording / reproducing apparatus 13A using a magneto-optical disk called MD (mini disk) as a recording medium is used as a storage device. The recording / reproducing apparatus 13A of this example is a deck that supports connection with the IEEE1394 bus line 16, and the case where the IRD 12 and the recording / reproducing apparatus 13A are connected with the IEEE1394 bus line 16 will be described. The IEEE 1394 compatible recording / reproducing apparatus 13A can accumulate text data including the jacket data and lyrics data together with the audio data of the music selected by the IRD 12. In connection using the IEEE 1394 bus line 16, a plurality of devices (for example, up to 64 devices) can be connected by so-called link connection, and storage devices can be connected to the IRD 12 via the IEEE 1394 bus line 16. Multiple units can be connected simultaneously.

  FIG. 9 shows an example of the configuration of the IRD 12. This IRD 12 has an input terminal T1, an analog video output terminal T2, an analog audio output terminal T3, an optical digital output interface 59, an IEEE 1394 interface 60, a man-machine interface 61, an IC card slot 62, a modem 63, and an infrared interface as external terminals or interfaces. 66.

  The input terminal T1 is a terminal to which a reception signal converted into a predetermined frequency by the LNB 25 is input. The analog video output terminal T2 is a terminal for supplying an analog video signal to the television receiver 14. The analog audio output terminal T3 is a terminal for supplying an analog audio signal to the television receiver 14, and the analog audio output terminal T4 is a terminal for supplying an analog audio signal to an analog input storage device. The optical digital output interface 59 conforms to IEC 958, and sends PCM audio data to an optical fiber cable (not shown). The IEEE 1394 interface 60 sends video data, audio data, various commands, and the like to an IEEE 1394 format bus line. The man-machine interface 61 sends input data based on an infrared signal from the remote control device 64 by the user to the control CPU 58. An IC card 65 is inserted into the IC card slot 62. The modem 63 is connected to the accounting server 5 via the telephone line 4. The infrared interface 66 is an interface for controlling the storage device by an infrared signal from the control CPU 58, and an infrared signal for controlling the storage device is transmitted from an infrared output unit 67 connected to the infrared interface 66 via a predetermined signal line. Is output.

  The tuner 51 selects a signal having a predetermined reception frequency from the reception signals supplied from the terminal T1 based on the setting signal from the control CPU 58, further performs demodulation and error correction processing, and outputs an MPEG transport stream. . The descrambler 52 receives the MPEG transport stream from the tuner 51, receives the descrambling key data stored in the IC card 65 via the IC card slot 62 and the control CPU 58, and uses this key data to decode the descrambler key data. Scramble. The transport IC 53 receives a command input by the user from the remote controller 64 via the man-machine interface 61 and the control CPU 58, and extracts MPEG video data and MPEG audio data of a desired television program from the transport stream. The MPEG video decoder 55 converts the MPEG video data supplied from the transport IC 53 into video data before data compression. The MPEG audio decoder 54 converts MPEG audio data supplied from the transport IC 53 into audio data (PCM audio data) before data compression. The DA converter 56 converts the audio data supplied from the MPEG audio decoder 54 into an analog audio signal and supplies the analog audio signal to the analog audio output terminal T3.

  The control CPU 58 performs processing of the entire IRD 12. In this case, work memories 58 a and 58 b are connected to the control CPU 58. The memory 58a is a rewritable memory, and MHEG data and audio additional information for generating a GUI screen from the transport stream received by the tuner 51 and extracted by the transport IC 53 are described. Are stored in the memory 58a. The memory 58b is a nonvolatile memory in which a program is set when the IRD 12 is manufactured, and various programs necessary for operating the IRD 12 are stored in advance. Examples of the program stored in the memory 58b include a resident program that is started based on MHEG data and generates a GUI screen, a process that controls a storage device connected to the IRD 12, and the like. .

  Further, a command input by the user using the remote control device 64 to the control CPU 58 is received via the man-machine interface 61. Further, a modem 63 is connected to the control CPU 58. Information necessary for charging is stored in the IC card 65. Information on the IC card 65 is sent to the accounting server 5 (FIG. 1) via the telephone line 4 using the modem 63.

  Based on the data stored in the memory 58a, the control CPU 58 forms a list page screen, a music information page screen, or GUI screen data. The screen data thus formed is written in a predetermined area of the buffer memory in the MPEG video decoder 55. As a result, as shown in FIG. 2, the list page of the music to be broadcast, the screen of the information page of each music, or the screen for GUI can be displayed in the designated area on the screen.

  Next, the operation of the IRD 12 shown in FIG. 9 will be described.

  When the user selects the channel of the music content distribution system described so far in the IRD 12 shown in FIG. 9, a GUI screen as shown in FIG. 2 is displayed on the screen of the television receiver 14.

  At this time, the reception signal input to the terminal T1 is supplied to the tuner 51. The tuner 51 selects a signal having a predetermined reception frequency from the reception signals based on the setting signal from the control CPU 58, and further performs demodulation and error correction processing to output an MPEG transport stream.

  The output of the tuner 51 is supplied to the descrambler 52. In the descrambler 52, descrambling key data stored in the IC card 65 is input via the IC card slot 62 and the control CPU 58, and the MPEG transport stream is descrambled using the key data. . The descrambled MPEG transport stream is sent to the transport IC 53.

  In the transport IC 53, a command input by the user from the remote control device 64 is input via the man-machine interface 61 and the control CPU 58. Then, in accordance with the command, MPEG video data and MPEG audio data of a desired television program are extracted from the transport stream and sent to the MPEG video decoder 55 and the MPEG audio decoder 54, respectively.

  Each data separation process in the transport IC 53 is executed by a demultiplexer built in the transport IC 53. FIG. 10 is a diagram showing the configuration of this demultiplexer, which includes a PID filter 81 and a section data filter 82. The PID filter 81 determines the PID (packet ID) of the input transport stream packet, separates the audio data and the video data, and supplies them to the respective decoders. Further, the audio additional information is separated and sent to the control CPU 58 side. The section data filter 82 separates desired section data and sends it to the control CPU 58 side.

  The MPEG video data sent to the MPEG video decoder 55 is converted into video data before data compression here, and then converted into a composite video signal in the NTSC conversion block 57, and then a television receiver from the analog video output terminal T2. Is output. The MPEG audio data sent to the MPEG audio decoder 54 is converted into audio data before being compressed here, and then converted into an analog audio signal by the DA converter 56, and then from the analog audio output terminal T3 to the television receiver. Is output.

  When music is selected from the music list 21B on the GUI screen shown in FIG. 2 and the audio data of the music is auditioned, MPEG audio data is extracted from the transport IC 53, decoded by the MPEG audio decoder 54, After digital / analog conversion by the DA converter 56, the signal is output from the analog audio output terminal T3 to the television receiver 14 (FIG. 1).

  When the download button 28 is pressed on the GUI screen shown in FIG. 2 to download the audio data, the audio data is extracted from the transport IC 53, and the analog audio output terminal T3, the optical digital output interface 59, or Audio data is output from any one of the IEEE 1394 interfaces 60.

  That is, as shown in FIG. 8, when a recording / reproducing apparatus 13A compatible with IEEE1394 is connected to the IEEE1394 interface 60, quadruple speed ATRAC data is extracted by the transport IC 53, and the IEEE1394 interface 60 is used to extract IEEE1394. It is sent to the corresponding recording / reproducing apparatus 13A. At this time, jacket data compressed by the JPEG method is extracted by the transport IC 53 and sent to the IEEE 1394-compatible recording / reproducing apparatus 13A via the IEEE 1394 interface 60. Further, at this time, text data such as lyrics and artist profiles are extracted by the transport IC 53 and sent to the IEEE 1394-compatible recording / reproducing apparatus 13A via the IEEE 1394 interface 60.

  When a storage device (a model not equipped with the IEEE 1394 interface) is connected to the optical digital output interface 59, MPEG audio data is extracted by the transport IC 53, decoded by the MPEG audio decoder 54, and then output to the optical digital output. PCM audio data is sent to the storage device via the interface 59.

  FIG. 11 is a block diagram showing an example of the configuration of a recording / reproducing apparatus 13A compatible with IEEE1394. This IEEE 1394 recording / reproducing apparatus 13A includes an IEEE 1394 interface 71, an optical digital input interface 72, an analog audio input terminal T12, and an analog audio output terminal T13. The IEEE 1394 interface 71 is directly connected to the storage / playback unit 75. The optical digital input interface 72 is connected to the recording / reproducing unit 75 via the ATRAC encoder 74. The analog audio input terminal T12 is connected to the ATRAC encoder 73 via the A / D converter 73. The analog audio output terminal T13 is connected to the recording / reproducing unit 75 via the D / A converter 78 and the ATRAC decoder 77. A disk (magneto-optical disk) 76 is set in the recording / reproducing unit 75, and recording / reproduction is performed on the disk 76. Although not shown here, a control CPU for performing overall control of the recording / reproducing apparatus 13A compatible with IEEE1394 and a man-machine interface are provided.

  Next, the recording operation of the recording / reproducing apparatus 13A compatible with IEEE1394 will be described.

  When the IEEE 1394 interface 71 and the IEEE 1394 interface 60 of the IRD 12 shown in FIG. 9 are connected, the audio data of the music transmitted from the IEEE 1394 interface 60, text data such as lyrics, and still image data such as a jacket are , Input from the IEEE 1394 interface 71 and recorded on the disk 76 by the recording / reproducing unit 75 as it is. As will be described later, at this time, each data is recorded on the disk 76 in the extended MD format. As will be described later, the copyright information of each data is also input from the IEEE 1394 interface 71 and recorded in the corresponding catalog information (TOC) area.

  When PCM audio data is input from the outside to the optical digital input interface 72, the input PCM audio data is encoded by the ATRAC encoder 74 and then recorded on the disk 76 by the recording / reproducing unit 75.

  When an analog audio signal is externally input to the analog audio input terminal T12, the input analog audio signal is analog / digital converted by the AD converter 73, encoded by the ATRAC encoder 74, and then recorded / reproduced by the recording / reproducing unit 75. Recorded on the disk 76.

  In other words, with this IEEE1394 compatible recording / reproducing apparatus 13A, only when the IRD 12 is connected with the IEEE1394 interface, the lyrics data and the still image data of the jacket are recorded together with the audio data of the music, and the optical digital interface is used. In the case of connection or analog audio connection, only audio data is recorded.

  During reproduction, a reproduction signal can be output from the IEEE 1394 interface 71 or the analog audio output terminal T13. When the lyrics data and the jacket data are recorded together with the music audio data on the disk 76 when the data is output from the IEEE 1394 interface 71, the music data is output to an IEEE 1394 compatible audio device (such as an amplifier). In addition, the lyrics data and the jacket data can be displayed on an IEEE 1394 compatible display or printed by an IEEE 1394 compatible printer.

  As described above, the recording / reproducing apparatus compatible with IEEE 1394 to which the present invention is applied can record and reproduce lyrics data and jacket data together with audio data of music.

  This recording / reproduction can be performed by using the extended MD format shown in FIG. As shown in this figure, audio data of music is recorded in the main data area by the ATRAC method. This is the same as the current MD format. A maximum of 74 minutes of ATRAC audio data is recorded in the main data (Main Data) area, and catalog information such as the recording position of each song is recorded in the audio data inventory information (User Table Of Contents) area. In addition to recording, auxiliary catalog information such as copy prohibition information for each song is recorded. In the extended MD format, the jacket data (still image data), the lyrics data (text data), and the like described above are further recorded in the auxiliary data (Aux Data) area of 2.8 Mbytes. The inventory information of the data recorded in this auxiliary data area is recorded in the auxiliary inventory information (Aux TOC) area. At this time, auxiliary inventory information such as copy prohibition information is also recorded in the auxiliary inventory information area for each still image data and text data. By using this format, jacket data and lyrics data can be recorded and reproduced together with the audio data of the music. In addition, compatibility with the current MD format can be maintained.

  Next, with reference to the flowchart of FIG. 13, the receiving facility shown in FIG. 9 refers to the processing when downloading ATRAC audio data of music as a music program and jacket data and lyrics data as additional audio information. explain.

  First, in the IRD 12, the user selects an EMD (Electric Music Download) channel, that is, a music broadcast channel that enables downloading of music data described so far (step 101). Specifically, a channel selection command is given to the remote control device 64 shown in FIG. 9 while watching the GUI screen displayed on the television receiver 14. In the IRD 12, the control CPU 58 receives a user channel selection command via the man-machine interface 61, sends a channel setting signal to the tuner 51, and sets a desired channel.

  When this channel is selected, the control CPU 58 refers to section data called PMT (Program Map Table) to determine whether there is MHEG data for forming a GUI screen (list screen) in the selected channel. Judgment is made (step 102). Here, when there is no MHEG data for the GUI screen, it is determined that the channel is not a channel for performing the download process of this example, and the process is terminated. When the above-described channel for transmitting ATRAC audio is selected, there is MHEG data for the GUI screen, and the control CPU 58 starts up a program for interpreting the MHEG data prepared in the work memory 58b in advance. The received MHEG data is interpreted (step 103).

  Then, based on the interpreted MHEG data, the control CPU 58 creates GUI screen image data, supplies the image data to the decoder 55, and displays it on the screen of the television receiver 14 connected to the IRD 12 ( Step 104). The GUI screen displayed at this time is, for example, the screen shown in FIG. Here, the control CPU 58 waits until the selection operation of the music displayed on this screen and the download operation of the selected music are performed by the key operation of the remote control device 64 (step 105). When a remote control signal is supplied in response to an operation to depress the portion 28 displayed as download, a get device program in a resident program prepared in advance in the memory 58b is started, and this get device program uses IEEE 1394. The device ID of the storage device 13A connected via the system bus line is acquired and transferred to the MHEG data execution processing unit (step 106). The device ID here is an identification code given in advance with a predetermined number of bits (64 bits in this case) for connection via an IEEE 1394 bus line. The device manufacturer code, device model type code, device The serial code and the like are set in an array according to a predetermined standard, and the type and function of the connected model can be determined by the control CPU 58 by determining the device ID using a program prepared in the memory 58b.

  When the device ID of the storage device to which the control CPU 58 is connected is acquired, image data for list display of the device connected to the IRD 12 is created based on the device ID, and the image data is supplied to the decoder 55. It is displayed on the screen of the television receiver 14 connected to the IRD 12 (step 107). Here, the control CPU 58 waits until the device selection operation displayed on this screen is performed by the key operation of the remote control device 64 (step 108). If a remote control signal corresponding to the selection operation of this device is supplied, it waits until the ATRAC data of the song instructed to be downloaded in step 105 is received. Then, still image data (JPEG data) such as jacket data of this song and text data such as lyrics are transmitted from the IEEE 1394 interface 60 to the bus line 16 to the selected device (storage device).

  At this time, the node ID set for the selected device is assigned to the data transmitted from the IEEE 1394 interface 60 as the transmission destination address. Further, isochronous transfer (synchronous transfer) is performed for ATRAC data, which is audio data of music, and asynchronous transfer (asynchronous transfer) is performed for JPEG data and text data. Control data that causes the destination device to execute processing for recording the transmitted ATRAC data and the like is also transmitted by asynchronous transfer. With this processing, the data sent to the bus line 16 is recorded in the state shown in FIG. 12 on a connected device, here a disc loaded in the recording / reproducing apparatus 13A compatible with IEEE1394.

  Then, the control CPU 58 determines whether or not downloading of all data relating to the music selected by the IEEE 1394 bus line 16 has been completed (step 110). If there is an instruction to download another song, the process returns to step 109 to download the song. If it is determined that the download process for all the songs selected in step 111 has been completed, the process related to download ends. When this ATRAC audio data or the like is downloaded, if this data is paid data, a predetermined charging process is performed (the details of the charging process are omitted here).

  By performing the processing in this manner, when a device as a storage device capable of recording ATRAC audio data is connected to the IRD 12 via an IEEE 1394 format bus line, ATRAC audio data or the like is transmitted. Based on the MHEG data transmitted from the side, a process of creating a list of connected devices is started, and the process itself is executed by a resident program prepared in advance in the IRD 12, and the list is displayed. A device for downloading ATRAC audio data or the like can be easily selected. Therefore, the list is displayed on the IRD 12 according to the MHEG data transmitted from the transmission side, but the details of the process for acquiring the device ID are actually executed by the resident program prepared in the IRD 12, An appropriate device ID acquisition process based on the actual configuration of the IRD 12 is performed. In particular, in the IEEE 1394 format bus line, a very large number of devices (for example, 64 units) can be connected. Therefore, the selection process when a plurality of devices are connected to the IRD 12 via the bus line is efficiently performed based on the list display. Yes.

  Next, a process of searching for a desired song by the user when downloading ATRAC audio data received by the IRD 12 as described above will be described. First, for example, when the GUI screen shown in FIG. 2 is displayed and the remote control device 64 is operated corresponding to pressing the reserved recording button 25 in the screen, the music search process is performed by the operation. This is executed when the control CPU 58 detects that an infrared signal has been input through the man-machine interface 61. When the operation of pressing the reserved recording button 25 is performed, the GUI screen is switched under the control of the control CPU 58, and a list of songs that can be reserved is displayed on the entire screen of the television receiver 14.

  This list display is performed based on text data indicating the song name and player name of each song. This text data is transmitted in a packet different from the above-mentioned lyrics text data. For example, as shown in FIG. 15, the text data for one song is a character string of a player name (artist name), It consists of a text data string arranged in the order of tab code, song name character string, and line feed code, and the text data of all songs delivered during a predetermined period (for example, one day) in this order. And repeatedly transmitted periodically from the transmission side.

  Based on this text data, a list of songs that can be reserved is displayed. Here, it is possible to simply display a list of text data in the order of broadcasting, but there is an operation of the remote control device 64 corresponding to pressing the search button in the list display screen, and the infrared signal generated by the operation is manned. When the control CPU 58 detects that an input has been made on the machine interface 61, a search based on the text data is started (the control CPU 58 detects the following other user operations as well). The flowchart of FIG. 14 is a diagram showing this search processing. The following description will be made based on the drawing. First, the control CPU 58 performs control to extract text data of the player name and the song title from the broadcast data. (Step 201).

  When the text data of the player name and the music title is extracted, the extracted data is stored in a memory connected to the control CPU 58. Here, when the user specifies the item to be searched using the remote control device 64 or the like, the control CPU 58 performs processing for passing the data of the corresponding row or column number to the resident program (step 202). When the user inputs a character string to be searched by operating the remote control device 64 (step 203), the character string to be searched is set as a variable to be referred to when the resident program executes the search process (step 204).

  Here, a search process for extracting a row or column including a search character from an item designated by the resident program is performed, and text data including the extracted row or column is set as the searched data (step 205). After this process, it is determined whether or not all items have been searched (step 206). If there is unsearched data, the process returns to step 205 to repeat the process, and all data has been searched. The control CPU 58 performs a control process for displaying a list of characters in a row or column designated from the text data set as the data retrieved in step 205 (step 207). In this control processing, image data for displaying the search result is supplied to the decoder 55, and the search result is displayed on the screen of the television receiver 14 connected to the IRD 12.

  If there are a plurality of player names and song names displayed as search results, it is further determined whether or not to perform a search (step 208). Return. When the search process ends, the user performs an input operation to select a desired song from the displayed player name and song name, and reserves the download of the selected song (step 209). This download reservation operation corresponds to the download push-down operation in step 105 in the flowchart of FIG. 13, and thereafter, processing for selecting the device in step 106 and later is performed.

  When the search process is performed in this way, it is easy to select a desired song download from the text data of the player name and song name distributed as a broadcast signal, and the number of songs distributed is large However, it is possible to easily download a song desired by the user. In particular, in the case of this example, the transmitted song name and performer name text data has a data structure that is continuously arranged with the addition of a tab code and a line feed code. Can be searched efficiently.

  In the above-described embodiment, the processing for downloading audio data called ATRAC audio to a storage device using a recording medium called MD (mini disk) has been described. When downloading the obtained audio data, image data, e-mail data, Internet content data, etc. to a connected storage device and recording them, when searching based on the text data attached to the main data It can also be applied to the processing.

  In addition, as a transmission path from the transmission side of audio data or the like to the reception facility, digital satellite broadcasting relayed by an artificial satellite is applied, but another transmission path for broadcasting may be applied. For example, an optical table or coaxial cable called cable television is used to transmit ATRAC audio data or the like through a predetermined channel of a transmission line in which the transmission side and the reception facility are directly connected by wire, and the reception facility A similar download may be performed on the side. Further, other transmission lines such as a telephone line may be used.

  In addition, the storage device and the device connected to the storage device are connected by an IEEE 1394 format bus line, but may be connected by a data transmission path of another format.

It is a block diagram which shows the structural example of the whole system by one embodiment of this invention. It is explanatory drawing which shows the example of the receiving screen by one embodiment of this invention. It is a block diagram which shows the structural example on the transmission side of the data by one embodiment of this invention. It is explanatory drawing which shows the example of transmission data by one embodiment of this invention. It is explanatory drawing which shows the example of the transmission state by one embodiment of this invention. It is explanatory drawing which shows the example of the packet structure by one embodiment of this invention. It is explanatory drawing which shows the transmission concept of MHEG data by one embodiment of this invention. It is a block diagram which shows the example of a connection by one embodiment of this invention. It is a block diagram which shows the structural example of IRD by one embodiment of this invention. It is a block diagram which shows the structural example of the demultiplexer by one embodiment of this invention. 1 is a block diagram illustrating a configuration example of a recording apparatus according to an embodiment of the present invention. It is explanatory drawing which shows the example of the data recording state to the disk by one embodiment of this invention. It is a flowchart which shows the example of a predetermined channel download process by one embodiment of this invention. It is a flowchart which shows the example of a search process by one embodiment of this invention. It is explanatory drawing which shows text data structures, such as a music title, by one embodiment of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 3 ... Reception equipment, 12 ... IRD, 13 ... Storage device, 13A ... Disc recording and reproducing apparatus corresponding to IEEE1394, 14 ... Television receiver, 58 ... Control CPU, 58a, 58b ... Working memory, 60, 71 ... IEEE1394 Interface, 61, 79a ... Man-machine interface, 66 ... Infrared signal interface, 67 ... Infrared signal output unit, 80 ... Demultiplexer

Claims (7)

Receiving means for receiving GUI data related to audio data and including at least lyrics data;
Display data created based on the GUI data is displayed on the display means, and when the audio data is being reproduced, lyrics data related to the audio data received by the receiving means is synchronized with the reproduction of the audio data. Display control means for displaying on the display means;
Storage control means for storing lyrics data related to audio data selected based on the display data in the storage means;
An information processing apparatus. The receiving means further receives copyright information of the lyrics data.
The information processing apparatus according to claim 1. The storage control means records the copyright information of the lyrics data together with the lyrics data in the storage means.
The information processing apparatus according to claim 2. Further comprising decryption means for decrypting the encrypted data;
The receiving means receives the encrypted GUI data,
The decoding means decodes the GUI data received by the receiving means.
The information processing apparatus according to claim 3. The display control means displays a lyrics button for displaying lyrics in the display data. When the lyrics button is selected, lyrics data related to the audio data is synchronized with reproduction of the audio data. Display on display means
The information processing apparatus according to claim 4. GUI data related to audio data, at least receiving GUI data including lyrics data;
Display the display data created based on the GUI data, and display the lyrics data related to the audio data received in synchronization with the reproduction of the audio data when the audio data is being reproduced;
Processing for storing lyrics data related to audio data selected based on the display data
Information processing method. GUI data related to audio data, at least receiving GUI data including lyrics data;
Display the display data created based on the GUI data, and display the lyrics data related to the audio data received in synchronization with the reproduction of the audio data when the audio data is being reproduced;
Processing for storing lyrics data related to audio data selected based on the display data
program.

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