WO2016052185A1 - 送信装置、送信方法、受信装置および受信方法 - Google Patents
送信装置、送信方法、受信装置および受信方法 Download PDFInfo
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Definitions
- the present invention relates to a transmission device, a transmission method, a reception device, and a reception method, and more particularly to a transmission device that transmits multichannel audio data.
- Patent Literature 1 describes the IEC 60958 standard.
- LPCM Linear Pulse Code Modulation
- transmission for two channels is defined in the IEC 60958-1 standard, and linear PCM is assigned to each channel in the IEC 60958-3 standard.
- the physical layer for coaxial output and optical output from the RCA pin terminal is standardized in the IEC 609588-1 standard, and the physical layer equivalent to the coaxial output is HDMI ARC (High-Definition Multimedia) Interface Audio Return Channel). Has been standardized.
- Audio applications include not only two-channel but also multi-channel applications, which have been mapped and transmitted on IEC 60958 using the IEC 61937 standard in a compressed bitstream transmission format.
- the quality of this multi-channel audio application has improved, lossless compression and the like have begun to be used, and there has been an increasing demand for transmission in the form of multi-channel linear PCM audio with high sound quality.
- the purpose of this technology is to enable good transmission of multi-channel audio data.
- a data acquisition unit that acquires multi-channel audio data of a predetermined number of channels, The multi-channel audio data has a sampling frequency corresponding to the predetermined number of channels,
- a data transmission unit that sequentially transmits the audio data of each channel constituting the multi-channel audio data to the reception side for each unit audio data via a predetermined transmission path;
- the transmitting apparatus further includes an information adding unit that adds information indicating the sampling frequency to the audio data transmitted by the data transmitting unit.
- multi-channel audio data of a predetermined number of channels is acquired by the data acquisition unit.
- the predetermined number of channels may be 6, 12, or 24.
- the multi-channel audio data has a sampling frequency corresponding to a predetermined number of channels.
- the data transmission unit sequentially transmits the audio data of each channel constituting the multi-channel audio data to the receiving side via the predetermined transmission path for each unit audio data.
- the information adding unit adds information indicating the sampling frequency to the audio data transmitted by the data transmitting unit.
- the predetermined transmission path may be a coaxial cable, an optical cable, an HDMI cable, or a display port cable.
- multi-channel audio data having a predetermined number of channels has a sampling frequency corresponding to the number of channels, and information indicating the sampling frequency is included in the audio data transmitted by the data transmission unit. It is to be added. Therefore, on the receiving side, the predetermined number of channels can be recognized based on the information indicating the sampling frequency, and the received audio data can be processed satisfactorily.
- the information adding unit may further add information indicating the correspondence between each channel and the speaker position to the audio data transmitted by the data transmitting unit.
- the receiving side can appropriately supply the audio data of each channel to the corresponding speaker.
- the present technology further comprising an information acquisition unit that acquires information of the sampling frequency supported by the reception side, the data transmission unit, when the reception side supports the sampling frequency corresponding to the predetermined number of channels, A predetermined number of channels of multi-channel audio data may be transmitted to the receiving side. This makes it possible to avoid transmission when the receiving side does not support multi-channel audio data.
- a user interface unit that displays a channel configuration of multi-channel audio data transmitted by the data transmission unit may be further provided. Thereby, the user can easily grasp what multi-channel audio data is being transmitted.
- a data receiving unit that sequentially receives audio data of each channel constituting multi-channel audio data of a predetermined number of channels for each unit audio data from a transmitting side via a predetermined transmission path,
- the multi-channel audio data has a sampling frequency corresponding to the predetermined number of channels,
- Information indicating the sampling frequency is added to the audio data received by the data receiving unit
- the receiving apparatus further includes a processing unit that recognizes the predetermined number of channels based on the information indicating the sampling frequency and processes the audio data received by the data receiving unit.
- the data receiving unit sequentially receives the audio data of each channel constituting the multi-channel audio data of the predetermined number of channels from the transmitting side for each unit audio data through the predetermined transmission path.
- the predetermined number of channels may be 6, 12, or 24.
- the predetermined transmission path may be a coaxial cable, an optical cable, an HDMI cable, or a display port cable.
- the multi-channel audio data has a sampling frequency corresponding to a predetermined number of channels.
- Information indicating the sampling frequency is added to the audio data received by the data receiving unit.
- the processing unit recognizes a predetermined number of channels based on the information indicating the sampling frequency, and processes the audio data received by the data receiving unit.
- the audio data of each channel constituting the multi-channel audio data having a predetermined number of channels has a sampling frequency corresponding to the number of channels and the audio data received by the data receiving unit. To which information indicating the sampling frequency is added. Therefore, the predetermined number of channels can be recognized based on the information indicating the sampling frequency, and the received audio data can be processed satisfactorily.
- information indicating the correspondence relationship between each channel and the speaker position is further added to the audio data received by the reception unit, and the processing unit, based on the information indicating the correspondence relationship,
- the audio data of each channel may be supplied to a corresponding speaker.
- the audio data of each channel can be appropriately supplied to the corresponding speaker.
- an information transmission unit that transmits information on a sampling frequency to be supported to the transmission side may be further provided.
- the transmitting side can easily grasp that the receiving side supports multi-channel audio data.
- a user interface unit that displays a channel configuration of multi-channel audio data received by the data receiving unit may be further provided. Thereby, the user can easily grasp what multi-channel audio data is being received.
- a data acquisition unit for acquiring multi-channel audio data of a predetermined number of channels;
- a data transmission unit that sequentially transmits the audio data of each channel to a reception side via a predetermined transmission path with a preamble added for each unit audio data,
- the preamble pattern added to the head unit audio data for each continuous unit audio data of the predetermined number of channels is a specific pattern indicating the head.
- multi-channel audio data of a predetermined number of channels is acquired by the data acquisition unit.
- the data transmission unit sequentially transmits the audio data of each channel to the reception side via a predetermined transmission path with a preamble added for each unit audio data.
- the preamble pattern added to the head unit audio data for each unit audio data having a predetermined number of channels is a specific pattern indicating the head.
- the preamble pattern added to the head unit audio data for each continuous unit audio data of a predetermined number of channels is a specific pattern indicating the head. Therefore, on the receiving side, the predetermined number of channels can be recognized based on the preamble added to the received unit audio data, and the received audio data can be processed satisfactorily.
- an information addition unit that adds information indicating a correspondence relationship between each channel and a speaker position to audio data transmitted by the data transmission unit may be further provided.
- the receiving side can appropriately supply the audio data of each channel to the corresponding speaker.
- a data receiving unit that sequentially receives audio data of each channel constituting multi-channel audio data of a predetermined number of channels in a state where a preamble is added for each unit audio data from a transmission side via a predetermined transmission path;
- the preamble pattern added to the head unit audio data for each continuous unit audio data of the predetermined number of channels is a specific pattern indicating the head,
- a processing unit for recognizing the predetermined number of channels based on a preamble pattern added to unit audio data sequentially received by the data receiving unit and processing the audio data received by the data receiving unit; It is in the receiving device.
- the data receiving unit sequentially receives the audio data of each channel constituting the multi-channel audio data of the predetermined number of channels from the transmitting side through the predetermined transmission path with the preamble added for each unit audio data.
- the preamble pattern added to the head unit audio data for each unit audio data having a predetermined number of channels is a specific pattern indicating the head.
- the processing unit recognizes a predetermined number of channels based on the preamble pattern added to the unit audio data sequentially received by the data receiving unit, and processes the audio data received by the data receiving unit.
- the preamble pattern added to the head unit audio data for each continuous unit audio data of a predetermined number of channels is a specific pattern indicating the head. Therefore, the predetermined number of channels can be recognized based on the preamble, and the received audio data can be processed satisfactorily.
- audio data received by the data receiving unit is further added with information indicating a correspondence relationship between each channel and a speaker position, and the processing unit is based on the information indicating the correspondence relationship.
- the audio data of each channel may be supplied to a corresponding speaker. As a result, the audio data of each channel can be appropriately supplied to the corresponding speaker.
- FIG. 60958 It is a figure which shows the structural example of the high-speed bus interface of an audio amplifier. It is a figure which shows the frame structure in IEC 60958 standard. It is a figure which shows the sub-frame structure in IEC 60958 standard. It is a figure which shows the signal modulation system in IEC 60958 standard. It is a figure which shows the channel coding of the preamble in IEC60958 standard. It is a figure which shows schematically the format of the channel status in IEC 60958 standard. It is a figure which shows the prescription
- FIG. 1 It is a figure which shows an example of the frame structure in the multi-channel transmission of 6 channels when the newly defined preamble is used instead of the preamble of “B”, “M”, “W” as the preamble. It is a figure which shows another example of the frame structure in 6 channel multi-channel transmission at the time of using the newly defined preamble. It is a block diagram which shows the structural example of AV system at the time of utilizing an optical cable as an IEC 60958 transmission line. It is a figure which shows the example which utilizes an HDMI transmission line and a display port transmission line as EC EC60958 transmission line.
- Embodiment> [Example of AV system configuration]
- FIG. 1 shows a configuration example of an AV system 10 as an embodiment.
- the AV system 10 includes a television receiver 100 as a sink device, an audio amplifier 200 as a repeater device, and a BD (Blu-Ray Disc) player 300 as a source device.
- a television broadcast receiving antenna 400 is connected to the television receiver 100 and the BD player 300.
- the audio amplifier 200 is connected to a 2-channel or multi-channel speaker system 500.
- the television receiver 100 and the audio amplifier 200 are connected via an HDMI cable 610.
- the television receiver 100 is provided with an HDMI terminal 101 to which an HDMI receiving unit (HDMI RX) 102 and a high-speed bus interface 103 constituting a communication unit are connected.
- the audio amplifier 200 is provided with an HDMI terminal 201a to which an HDMI transmission unit (HDMI) TX) 202a and a high-speed bus interface 203a constituting a communication unit are connected.
- HDMI HDMI transmission unit
- One end of the above-described HDMI cable 610 is connected to the HDMI terminal 101 of the television receiver 100, and the other end of the HDMI cable 610 is connected to the HDMI terminal 201 a of the audio amplifier 200.
- the audio amplifier 200 and the BD player 300 are connected via an HDMI cable 620.
- the audio amplifier 200 is provided with an HDMI terminal 201b to which an HDMI receiving unit (HDMI RX) 202b and a high-speed bus interface 203b constituting a communication unit are connected.
- the BD player 300 is provided with an HDMI terminal 301 to which an HDMI transmission unit (HDNI TX) 302 and a high-speed bus interface 303 constituting a communication unit are connected.
- HDMI terminal 201b to which an HDMI receiving unit (HDMI RX) 202b and a high-speed bus interface 203b constituting a communication unit are connected.
- HDMI terminal 301 to which an HDMI transmission unit (HDNI TX) 302 and a high-speed bus interface 303 constituting a communication unit are connected.
- HDMI cable 620 One end of the above-described HDMI cable 620 is connected to the HDMI terminal 201 b of the audio amplifier 200, and the other end of the HDMI cable 620 is connected to the HDMI terminal 301 of the BD
- FIG. 2 shows a configuration example of the television receiver 100.
- the television receiver 100 includes an HDMI terminal 101, an HDMI receiving unit 102, a high-speed bus interface 103, and a SPDIF (Sony Philips Digital Interface) transmission circuit 104.
- the television receiver 100 includes an antenna terminal 105, a digital tuner 106, an MPEG decoder 107, a video signal processing circuit 108, a graphic generation circuit 109, a panel drive circuit 110, and a display panel 111. Yes.
- the television receiver 100 includes an audio signal processing circuit 112, an audio amplification circuit 113, a speaker 114, an Ethernet interface (Ethernet I / F) 115, and a network terminal 116.
- the television receiver 100 includes an internal bus 120, a CPU 121, a flash ROM 122, an SDRAM (Synchronous RAM) 123, a display control unit 124, a remote control reception unit 125, a remote control transmitter 126, and a power supply unit 127.
- a CPU 121 a central processing circuit 116
- SDRAM Synchronous RAM
- the CPU 121 controls the operation of each unit of the television receiver 100.
- the flash ROM 122 stores control software and data.
- the SDRAM 123 constitutes a work area for the CPU 121.
- the CPU 121 develops the software and data read from the flash ROM 122 on the SDRAM 123 to activate the software, and controls each unit of the television receiver 100.
- the remote control receiving unit 125 receives a remote control signal (remote control code) transmitted from the remote control transmitter 126 and supplies it to the CPU 121.
- the CPU 121 controls each part of the television receiver 100 based on the remote control code.
- a remote control unit is shown as the user instruction input unit.
- the user instruction input unit has other configurations, for example, a touch panel unit that inputs an instruction by proximity / touch, a mouse, a keyboard, a camera It may be a gesture input unit that detects an instruction input, a voice input unit that inputs an instruction by voice, and the like.
- the antenna terminal 105 is a terminal for inputting a television broadcast signal received by a receiving antenna (not shown).
- the digital tuner 106 processes a television broadcast signal input to the antenna terminal 105 and generates a partial TS (Transport Stream) (TS packet of video data, audio data) from a predetermined transport stream corresponding to the user's selected channel. TS packet) is extracted.
- TS Transport Stream
- the digital tuner 106 extracts PSI / SI (Program Specific Information / Service Information) from the obtained transport stream and outputs it to the CPU 121.
- PSI / SI Program Specific Information / Service Information
- the process of extracting a partial TS of an arbitrary channel from a plurality of transport streams obtained by the digital tuner 106 is performed by obtaining packet ID (PID) information of the arbitrary channel from PSI / SI (PAT / PMT). It becomes possible.
- PID packet ID
- the MPEG decoder 107 decodes a video PES (Packetized Elementary Stream) packet formed of TS packets of video data obtained by the digital tuner 106 to obtain image data. Also, the MPEG decoder 107 performs decoding processing on the audio PES packet constituted by the TS packet of audio data obtained by the digital tuner 106 to obtain audio data.
- a video PES Packetized Elementary Stream
- the video signal processing circuit 108 and the graphic generation circuit 109 perform scaling processing (resolution conversion processing) and graphic processing on the image data obtained by the MPEG decoder 107 or the image data received by the HDMI receiving unit 102 as necessary. Data superimposition processing is performed.
- the panel drive circuit 110 drives the display panel 111 based on the video (image) data output from the graphic generation circuit 109.
- the display control unit 124 controls the display on the display panel 111 by controlling the graphics generation circuit 109 and the panel drive circuit 110.
- the display panel 111 includes, for example, an LCD (Liquid Crystal Display), a PDP (Plasma Display Panel), an organic EL panel (Organic Electro-Luminescence Panel), and the like.
- the display control unit 124 may directly control the display on the display panel 111.
- the CPU 121 and the display control unit 124 may be a single chip or a plurality of cores.
- the power supply unit 127 supplies power to each unit of the television receiver 100.
- the power supply unit 127 may be an AC power supply or a battery (storage battery, dry battery).
- the audio signal processing circuit 112 performs necessary processing such as D / A conversion on the audio data obtained by the MPEG decoder 107.
- the audio amplifier circuit 113 amplifies the audio signal output from the audio signal processing circuit 112 and supplies the amplified audio signal to the speaker 114.
- the speaker 114 may be monaural or stereo. Further, the number of speakers 114 may be one, or two or more.
- the speaker 114 may be an earphone or a headphone. Moreover, the speaker 114 may correspond to 2.1 channel, 5.1 channel, or the like.
- the speaker 114 may be connected to the television receiver 100 wirelessly.
- the speaker 114 may be another device.
- the network terminal 116 is a terminal connected to the network, and is connected to the Ethernet interface 115.
- the CPU 121, flash ROM 122, SDRAM 123, Ethernet interface 115, and display control unit 124 are connected to the internal bus 120.
- the HDMI receiving unit (HDMI sink) 102 receives baseband image (video) and audio data supplied to the HDMI terminal 101 via the HDMI cable by communication conforming to HDMI.
- the high-speed bus interface 103 is an interface of a bidirectional communication path configured using a reserved line and an HPD line that constitute an HDMI cable.
- the SPDIF transmission circuit 104 is a circuit for transmitting a digital audio transmission signal (hereinafter referred to as “SPDIF signal” as appropriate) of the IEC 60958 standard.
- the SPDIF transmission circuit 104 is a transmission circuit that conforms to the IEC 60958 standard.
- the SPDIF transmission circuit 104 generates an SPDIF signal including the audio data of each channel using the audio data SA of each channel of two channels or multichannels.
- the audio data SA is obtained by the MPEG decoder 107, for example, and audio data of 2 channels, 5.1 channels, 7.1 channels, 10.2 channels, 22.2 channels, etc. can be considered. Details of the SPDIF signal will be described later.
- the high-speed bus interface 103 is inserted between the Ethernet interface 115 and the HDMI terminal 101.
- the high-speed bus interface 103 supplies received data received from the counterpart device from the HDMI cable via the HDMI terminal 101 to the CPU 121 via the Ethernet interface 115.
- the high-speed bus interface 103 transmits transmission data supplied from the CPU 121 through the Ethernet interface 115 to the counterpart device from the HDMI terminal 101 via the HDMI cable. Further, the high-speed bus interface 103 transmits the SPDIF signal generated by the SPDIF transmission circuit 104 to the counterpart device from the HDMI terminal 101 via the HDMI cable.
- the content data when the received content data is sent to the network, the content data is output to the network terminal 116 via the Ethernet interface 115.
- the received content data when the received content data is transmitted to the bidirectional communication path of the HDMI cable, the content data is output to the HDMI terminal 101 via the Ethernet interface 115 and the high-speed bus interface 103.
- it before outputting the image data, it may be transmitted after being encrypted using a copyright protection technology such as HDCP, DTCP, DTCP +, or the like.
- the operation of the television receiver 100 shown in FIG. 2 will be briefly described.
- the television broadcast signal input to the antenna terminal 105 is supplied to the digital tuner 106.
- the digital tuner 106 processes the television broadcast signal and outputs a predetermined transport stream corresponding to the user's selected channel. From the transport stream, a partial TS (video data TS packet, audio data TS packet) is output. Are extracted, and the partial TS is supplied to the MPEG decoder 107.
- video data is obtained by performing a decoding process on a video PES packet composed of TS packets of video data.
- This video data is supplied to the panel drive circuit 110 after scaling processing (resolution conversion processing), graphics data superimposition processing, and the like are performed in the video signal processing circuit 108 and the graphic generation circuit 109 as necessary.
- scaling processing resolution conversion processing
- graphics data superimposition processing and the like are performed in the video signal processing circuit 108 and the graphic generation circuit 109 as necessary.
- the display panel 111 displays an image corresponding to the user's selected channel.
- audio data is obtained by performing a decoding process on the audio PES packet configured by the TS packet of the audio data.
- the audio data is subjected to necessary processing such as D / A conversion by the audio signal processing circuit 112, further amplified by the audio amplification circuit 113, and then supplied to the speaker 114. Therefore, sound corresponding to the user's selected channel is output from the speaker 114.
- content data (image data, audio data) supplied from the network terminal 116 to the Ethernet interface 115 or supplied from the HDMI terminal 101 to the Ethernet interface 115 through the high-speed bus interface 103 is supplied to the MPEG decoder 107. . Thereafter, the operation is the same as that at the time of receiving the television broadcast signal described above, an image is displayed on the display panel 111, and sound is output from the speaker 114.
- the HDMI receiving unit 102 acquires image data and audio data transmitted to the HDMI terminal 101 via the HDMI cable.
- the image data is supplied to the video signal processing circuit 108.
- the audio data is supplied to the audio signal processing circuit 112. Thereafter, the operation is the same as that at the time of receiving the television broadcast signal described above, an image is displayed on the display panel 111, and sound is output from the speaker 114.
- the SPDIF signal including the audio data of each channel of 2-channel or multi-channel generated by the SPDIF transmission circuit 104 is supplied to the high-speed bus interface 103. Then, the SPDIF signal is transmitted from the HDMI terminal 101 to the audio amplifier 200 via the HDMI cable 610 by the high-speed bus interface 103.
- FIG. 3 shows a configuration example of the audio amplifier 200.
- the audio amplifier 200 includes HDMI terminals 201a and 201b, an HDMI transmission unit 202a, an HDMI reception unit 202b, high-speed bus interfaces 203a and 203b, and an SPDIF reception circuit 204.
- the audio amplifier 200 also includes an MPEG decoder 205, a video / graphic processing circuit 206, an audio processing circuit 207, an audio amplification circuit 208, and an audio output terminal 209.
- the audio amplifier 200 includes an Ethernet interface 210, an internal bus 211, a CPU 212, a flash ROM 213, a DRAM 214, a display control unit 215, a panel drive circuit 216, a display panel 217, a power supply unit 218, and a remote controller.
- a receiving unit 219 and a remote control transmitter 220 are included.
- the CPU 212 controls the operation of each part of audio amplifier 200.
- the flash ROM 213 stores control software and data.
- the DRAM 214 constitutes a work area for the CPU 212.
- the CPU 212 develops software and data read from the flash ROM 213 on the DRAM 214 and activates the software to control each unit of the audio amplifier 200.
- the CPU 212, flash ROM 213, DRAM 214, Ethernet interface 210, and display control unit 215 are connected to the internal bus 211.
- the remote control receiving unit 219 receives a remote control signal (remote control code) transmitted from the remote control transmitter 220 and supplies it to the CPU 212.
- the CPU 212 controls each part of the audio amplifier 200 based on the remote control code.
- a remote control unit is shown as the user instruction input unit.
- the user instruction input unit has other configurations, for example, a touch panel unit that inputs an instruction by proximity / touch, a mouse, a keyboard, a camera It may be a gesture input unit that detects an instruction input, a voice input unit that inputs an instruction by voice, and the like.
- the HDMI transmission unit (HDMI source) 202a transmits baseband video (image) and audio data from the HDMI terminal 201a to the HDMI cable through communication conforming to HDMI.
- the HDMI receiving unit (HDMI sink) 202b receives baseband video (image) and audio data supplied to the HDMI terminal 201b via the HDMI cable by communication conforming to HDMI. Details of the HDMI transmitting unit 202a and the HDMI receiving unit 202b will be described later.
- the high-speed bus interfaces 203a and 203b are bidirectional communication interfaces using a reserved line and an HPD line that constitute an HDMI cable. Details of the high-speed bus interfaces 203a and 203b will be described later.
- the SPDIF receiving circuit 204 is a circuit for receiving an SPDIF signal (IEC 60958 standard digital audio transmission signal).
- the SPDIF receiving circuit 204 is a receiving circuit that conforms to the IEC 60958 standard. In this embodiment, the SPDIF receiving circuit 204 receives an SPDIF signal including audio data of each channel of 2-channel or multi-channel, and outputs audio data of each channel.
- the MPEG decoder 205 decodes the partial TS supplied to the Ethernet interface 210 via the high-speed bus interface 203a. In this case, audio data is obtained by performing decoding processing on audio PES packets in the partial TS.
- the audio processing circuit 207 performs necessary processing such as D / A conversion on the audio data of each channel of 2-channel or multi-channel obtained by the MPEG decoder 205 or received by the SPDIF receiving circuit 204.
- the audio amplification circuit 208 amplifies the 2-channel or multi-channel audio signals obtained by the audio processing circuit 207 and outputs the amplified signals to the audio output terminal 209. Note that a 2-channel or multi-channel speaker system 500 is connected to the audio output terminal 209.
- the audio processing circuit 207 further performs necessary processing on the audio data obtained by the HDMI receiving unit 202b, and then supplies the audio data to the HDMI transmitting unit 202a.
- the video / graphic processing circuit 206 supplies the video (image) data obtained by the HDMI receiving unit 202b to the HDMI transmitting unit 202a after processing such as superimposition of graphics data.
- the display control unit 215 controls the panel drive circuit 216 and controls the display on the display panel 217 in order to perform, for example, user interface display or status display of the audio amplifier 200.
- the display panel 217 includes, for example, an LCD (Liquid Crystal Display), an organic EL panel (Organic Electro-Luminescence Panel), and the like.
- the display control unit 215 may directly control the display on the display panel 217.
- the CPU 212 and the display control unit 215 may be a single chip or a plurality of cores.
- the power supply unit 218 supplies power to each unit of the audio amplifier 200.
- the power supply unit 218 may be an AC power supply or a battery (storage battery, dry battery).
- the HDMI receiving unit 202b acquires video (image) data and audio data transmitted from the BD player 300 via the HDMI cable 620 to the HDMI terminal 201b.
- the video data and audio data are supplied to the HDMI transmission unit 202a via the video / graphic processing circuit 206 and the audio processing circuit 207, respectively, and the television receiver 100 via the HDMI cable 610 connected to the HDMI terminal 202a. Sent to.
- the high-speed bus interface 203a receives a partial TS transmitted from the television receiver 100 through a predetermined line of the HDMI cable 610 connected to the HDMI terminal 201a.
- the partial TS is supplied to the MPEG decoder 205 via the Ethernet interface 211.
- the MPEG decoder 205 the PES packet of the audio data constituting the partial TS is decoded to obtain audio data of each channel of 2 channels or multi channels.
- the audio data is supplied to the audio processing circuit 207 and subjected to necessary processing such as D / A conversion.
- necessary processing such as D / A conversion.
- the audio signal of each channel output from the audio processing circuit 207 is amplified and output to the audio output terminal 209. Therefore, 2-channel or multi-channel audio output can be obtained from the speaker system 500.
- an SPDIF signal including audio data of each channel of two channels or multichannels transmitted from the television receiver 100 through a predetermined line of the HDMI cable 610 connected to the HDMI terminal 201a is received.
- the SPDIF signal is supplied to the SPDIF reception circuit 204.
- the SPDIF receiving circuit 204 processes the SPDIF signal and obtains audio data of each channel of two channels or multichannels.
- the audio data is supplied to the audio processing circuit 207 and subjected to necessary processing such as D / A conversion.
- necessary processing such as D / A conversion.
- the audio signal of each channel output from the audio processing circuit 207 is amplified and output to the audio output terminal 209. Therefore, 2-channel or multi-channel audio output can be obtained from the speaker system 500.
- the partial TS received by the high-speed bus interface 203a and supplied to the Ethernet interface 210 as described above is supplied as transmission data to the high-speed bus interface 203b. Therefore, these partial TS are transmitted to the BD player 300 via the HDMI cable 620 connected to the HDMI terminal 201b.
- FIG. 4 shows a configuration example of the BD player 300.
- the BD player 300 includes an HDMI terminal 301, an HDMI transmission unit 302, and a high-speed bus interface 303.
- the BD player 300 includes an internal bus 304, a CPU (Central Processing Unit) 305, a flash ROM (Read Only Memory) 306, an SDRAM (Synchronous Random Access Memory) 307, a display control unit 308, and a remote control reception. 309 and a remote control transmitter 310.
- a CPU Central Processing Unit
- flash ROM Read Only Memory
- SDRAM Synchronous Random Access Memory
- the BD player 300 includes a storage (recording) medium control interface 311, a BD (Blu-Ray-Disc) drive 312 a, an HDD (Hard disk drive) 312 b, an SSD (Solid State Drive) 312 c, and an Ethernet interface (Ethernet). I / F) 313 and a network terminal 314.
- the BD player 300 includes an MPEG (Moving Picture Picture Expert Group) decoder 315, a graphic generation circuit 316, a video output terminal 317, and an audio output terminal 318.
- MPEG Motion Picture Picture Expert Group
- the BD player 300 includes a panel drive circuit 319, a display panel 320, and a power supply unit 321.
- the CPU 305, flash ROM 306, SDRAM 307, storage medium control interface 311, Ethernet interface 313, and MPEG decoder 315 are connected to the internal bus 304.
- the CPU 305 controls the operation of each part of the BD player 300.
- the flash ROM 306 stores control software and data.
- the SDRAM 307 constitutes a work area for the CPU 305.
- the CPU 305 develops software and data read from the flash ROM 306 on the SDRAM 307 to activate the software, and controls each part of the BD player 300.
- the remote control receiving unit 309 receives a remote control signal (remote control code) transmitted from the remote control transmitter 310 and supplies it to the CPU 305.
- the CPU 305 controls each part of the BD player 300 according to the remote control code.
- the remote control unit is shown as the user instruction input unit.
- the user instruction input unit has other configurations, for example, a switch, a wheel, a touch panel unit for inputting an instruction by proximity / touch, a mouse It may be a keyboard, a gesture input unit for detecting an instruction input with a camera, a voice input unit for inputting an instruction by voice, or the like.
- the BD drive 312a records content data on a BD disc as a disc-shaped recording medium, or reproduces content data from the BD disc.
- the HDD 312b records content data or reproduces the content data.
- the SSD 312c records content data in a semiconductor memory such as a memory card or reproduces content data from the semiconductor memory.
- the BD drive 312a, the HDD 312b, and the SSD 312c are connected to the internal bus 304 via the storage medium control interface 311.
- a SATA interface is used as an interface for the BD drive 312a and the HDD 312b.
- a SATA interface or a PCIe interface is used as an interface for the SSD 312c.
- the MPEG decoder 315 performs decoding processing on the MPEG2 stream reproduced by the BD drive 312a, the HDD 312b, or the SSD 312c to obtain image and audio data.
- the graphic generation circuit 316 performs graphics data superimposition processing on the image data obtained by the MPEG decoder 315 as necessary.
- the video output terminal 317 outputs image data output from the graphic generation circuit 316.
- the audio output terminal 318 outputs the audio data obtained by the MPEG decoder 315.
- the panel drive circuit 319 drives the display panel 320 based on the video (image) data output from the graphic generation circuit 316.
- the display control unit 308 controls the display on the display panel 320 by controlling the graphics generation circuit 316 and the panel drive circuit 319.
- the display panel 320 includes, for example, an LCD (Liquid Crystal Display), a PDP (Plasma Display Panel) organic EL panel (Organic Electro-Luminescence Panel), or the like.
- the power supply unit 321 supplies power to each unit of the BD player 300.
- the power supply unit 321 may be an AC power supply or a battery (storage battery, dry battery).
- the HDMI transmission unit (HDMI source) 302 transmits baseband image (video) and audio data from the HDMI terminal 301 by communication conforming to HDMI.
- the high-speed bus interface 303 is an interface of a bidirectional communication path configured using a reserved line and an HPD line that configure an HDMI cable.
- the high-speed bus interface 303 is inserted between the Ethernet interface 313 and the HDMI terminal 301.
- the high-speed bus interface 303 transmits the transmission data supplied from the CPU 305 from the HDMI terminal 301 to the counterpart device via the HDMI cable.
- the high-speed bus interface 303 supplies reception data received from the counterpart device from the HDMI cable via the HDMI terminal 301 to the CPU 305.
- the operation of the BD player 300 shown in FIG. 4 will be briefly described.
- content data to be recorded is acquired via a digital tuner (not shown), from the network terminal 314 via the Ethernet interface 311, or from the HDMI terminal 301 via the high-speed bus interface 303.
- the content data is input to the storage medium control interface 311 and recorded on the BD disc by the BD drive 312a, on the HDD 312b, or on the semiconductor memory by the SSD 312c.
- content data (MPEG stream) reproduced by the BD drive 312a, HDD 312b, or SSD 312c is supplied to the MPEG decoder 315 via the storage medium control interface 311.
- the MPEG decoder 315 performs decoding processing on the reproduced content data to obtain baseband image and audio data.
- the image data is output to the video output terminal 317 through the graphic generation circuit 316.
- Audio data is output to the audio output terminal 318.
- the image data obtained by the MPEG decoder 315 is supplied to the panel drive circuit 319 through the graphic generation circuit 316 according to the user operation, and the reproduced image is displayed on the display panel 320.
- the audio data obtained by the MPEG decoder 315 is supplied to a speaker (not shown) according to a user operation, and audio corresponding to the reproduced image is output.
- the image and audio data obtained by the MPEG decoder 315 are transmitted through the HDMI TMDS channel during the reproduction, the image and audio data are supplied to the HDMI transmission unit 302 and packed. The data is output from the HDMI transmission unit 302 to the HDMI terminal 301.
- the content data reproduced by the BD drive 312a, the HDD 312b, or the SSD 312c is transmitted to the network during reproduction, the content data is output to the network terminal 314 via the Ethernet interface 313.
- the content data reproduced by the BD drive 312a, the HDD 312b, or the SSD 312c is sent to the bidirectional communication path of the HDMI cable 620 during reproduction, the content data is transmitted via the high-speed bus interface 303.
- Output to terminal 301 Before outputting the image data, it may be transmitted after being encrypted using a copyright protection technology such as HDCP, DTCP, DTCP +, or the like.
- FIG. 5 shows a configuration example of the HDMI receiving unit 102 of the television receiver 100 and the HDMI transmitting unit 202a of the audio amplifier 200 in the AV system 10 of FIG. Note that the configuration example of the HDMI receiving unit 202b of the audio amplifier 200 and the HDMI transmitting unit 302 of the BD player 300 are the same, and thus the description thereof is omitted.
- the HDMI transmitting unit 202a is an effective image section that is a section obtained by removing a horizontal blanking period and a vertical blanking period from a section from a certain vertical synchronization signal to the next vertical synchronization signal (hereinafter referred to as “video field” as appropriate).
- video field a vertical synchronization signal
- active video period a differential signal of image data for one screen of baseband (uncompressed) is transmitted to the HDMI receiving unit 102 in one direction through a plurality of channels.
- the HDMI transmission unit 202a receives a plurality of differential signals corresponding to audio data and control packets (Control Packets) accompanying the image data, other auxiliary data, and the like in the horizontal blanking period and the vertical blanking period.
- the channel is transmitted to the HDMI receiving unit 102 in one direction.
- the HDMI transmission unit 202 a includes a source signal processing unit 71 and an HDMI transmitter 72.
- the source signal processing unit 71 is supplied with baseband uncompressed image (Video) and audio (Audio) data.
- the source signal processing unit 71 performs necessary processing on the supplied image and audio data and supplies the processed image and audio data to the HDMI transmitter 72. Further, the source signal processing unit 71 exchanges control information, status notification information (Control / Status), and the like with the HDMI transmitter 72 as necessary.
- the HDMI transmitter 72 converts the image data supplied from the source signal processing unit 71 into corresponding differential signals, and connects the HDMI cable 610 with the three TMDS channels # 0, # 1, and # 2, which are a plurality of channels. The data is transmitted in one direction to the HDMI receiving unit 102 connected via the network.
- auxiliary data auxiliary data supplied from the transmitter 72 and the source signal processing unit 71, the vertical synchronization signal (VSYNC), and the horizontal synchronization signal (HSYNC).
- the transmitter 72 transmits pixel clocks synchronized with image data transmitted through the three TMDS channels # 0, # 1, and # 2 to the HDMI receiving unit 102 connected via the HDMI cable 610 using the TMDS clock channel. Send.
- the HDMI receiving unit 102 receives a differential signal corresponding to image data transmitted in one direction from the HDMI transmitting unit 202a through a plurality of channels in the active video section, and also has a horizontal blanking period and a vertical blanking period.
- the differential signals corresponding to the auxiliary data and the control data transmitted from the HDMI transmitting unit 202a are received through a plurality of channels.
- the HDMI receiving unit 102 includes an HDMI receiver 81 and a sync signal processing unit 82.
- the HDMI receiver 81 is a TMDS channel # 0, # 1, # 2, and a differential signal corresponding to image data transmitted in one direction from the HDMI transmission unit 202a connected via the HDMI cable 610; A differential signal corresponding to auxiliary data and control data is received in synchronization with a pixel clock transmitted from the HDMI transmission unit 202a through the TMDS clock channel. Further, the HDMI receiver 81 converts the differential signal into corresponding image data, auxiliary data, and control data, and supplies them to the sync signal processing unit 82 as necessary.
- the sync signal processing unit 82 performs necessary processing on the data supplied from the HDMI receiver 81 and outputs the processed data. In addition, the sync signal processing unit 82 exchanges control information, status notification information (Control / Status), and the like with the HDMI receiver 81 as necessary.
- the HDMI transmission channel includes three TMDS channels for serially transmitting image data, auxiliary data, and control data in one direction in synchronization with the pixel clock from the HDMI transmitting unit 202a to the HDMI receiving unit 102.
- TMDS channels for serially transmitting image data, auxiliary data, and control data in one direction in synchronization with the pixel clock from the HDMI transmitting unit 202a to the HDMI receiving unit 102.
- # 0, # 1, and # 2 and a TMDS clock channel as a transmission channel for transmitting a pixel clock
- transmission channels called a DDC (Display Data Channel) 83 and a CEC line 84 are transmission channels called a DDC (Display Data Channel) 83 and a CEC line 84.
- the DDC 83 is composed of two lines (signal lines) (not shown) included in the HDMI cable 610, and the source device receives E-EDID (Enhanced Extended Extended Display Identification) from the sink device connected via the HDMI cable 610. Used for reading. That is, the sink device has an EDIDROM 85. The source device reads the E-EDID stored in the EDIDROM 85 from the sink device connected via the HDMI cable 610 via the DDC 83, and recognizes the settings and performance of the sink device based on the E-EDID. To do.
- E-EDID Enhanced Extended Extended Display Identification
- the CEC line 84 is composed of one line (not shown) included in the HDMI cable 610, and is used for bidirectional communication of control data between the source device and the sink device.
- the HDMI cable 610 includes a line 86 connected to a pin called HPD (Hot Plug Detect). The source device can detect the connection of the sink device using the line 86. Further, the HDMI cable 610 includes a line 87 used for supplying power from the source device to the sink device. Further, the HDMI cable 610 includes a reserved line 88.
- HPD Hot Plug Detect
- FIG. 6 shows sections of various transmission data when image data of horizontal ⁇ vertical 1920 pixels ⁇ 1080 lines is transmitted in the TMDS channel.
- a video field 24 Video Data Period
- a data island period 25 Data Island Period
- a video field in which transmission data is transmitted using the three TMDS channels of HDMI There are three types of sections, namely, control section 26 (Control26Period).
- the video field period is a period from a rising edge (Active Edge) of a certain vertical synchronizing signal to a rising edge of the next vertical synchronizing signal, and includes a horizontal blanking period 22 (Horizontal Blanking) and a vertical blanking period 23 ( Vertical Blanking) and an effective pixel section 21 (Active Video) that is a section obtained by removing the horizontal blanking period and the vertical blanking period from the video field section.
- the video data section 24 is assigned to the effective pixel section 21.
- data of 1920 pixels (pixels) ⁇ 1080 lines of effective pixels (Active Pixel) constituting uncompressed image data for one screen is transmitted.
- the data island period 25 and the control period 26 are assigned to the horizontal blanking period 22 and the vertical blanking period 23.
- auxiliary data (Auxiliary Data) is transmitted.
- the data island section 25 is allocated to a part of the horizontal blanking period 22 and the vertical blanking period 23.
- audio data packets that are not related to the control among the auxiliary data are transmitted.
- the control section 26 is allocated to other portions of the horizontal blanking period 22 and the vertical blanking period 23.
- vertical synchronization signals, horizontal synchronization signals, control packets, and the like, which are data related to control, of auxiliary data are transmitted.
- FIG. 7 shows a pin arrangement of the HDMI connector.
- This pin arrangement is an example of type A (type-A).
- TMDS Data # i + which is the differential signal of TMDS channel #i
- the two lines that transmit TMDS Data # i- are two lines that are assigned TMDS Data # i + (the pin number is 1). , 4 and 7) and TMDS Data # i- assigned pins (pin numbers 3, 6 and 9).
- the CEC line 84 through which the CEC signal, which is control data, is transmitted is connected to the pin with the pin number 13, and the pin with the pin number 14 is a reserved pin.
- a line through which an SDA (Serial Data) signal such as E-EDID is transmitted is connected to a pin having a pin number of 16 and an SCL (Serial Clock) which is a clock signal used for synchronization when the SDA signal is transmitted and received.
- a line through which a signal is transmitted is connected to a pin having a pin number of 15.
- the above-described DDC 83 includes a line for transmitting the SDA signal and a line for transmitting the SCL signal.
- the HPD line 86 for detecting the connection of the sink device by the source device is connected to the pin having the pin number 19. Further, as described above, the power supply line 87 for supplying power is connected to the pin having the pin number 18.
- FIG. 8 shows a configuration example of the high-speed bus interface 103 of the television receiver 100 in the AV system 10 of FIG.
- the Ethernet interface 115 performs LAN (Local Area Network) communication, that is, transmission / reception of an Ethernet signal, using a transmission path configured by a pair of a reserved line and an HPD line among a plurality of lines constituting the HDMI cable 610.
- the SPDIF transmission circuit 104 transmits an SPDIF signal using the transmission path constituted by the above-described pair of lines.
- the television receiver 100 includes a LAN signal transmission circuit 441, a terminating resistor 442, AC coupling capacitors 443 and 444, a LAN signal reception circuit 445, a subtraction circuit 446, addition circuits 449 and 450, and an amplifier 451. These constitute the high-speed bus interface 103.
- the television receiver 100 includes a choke coil 461, a resistor 462, and a resistor 463 that constitute the plug connection transmission circuit 128.
- a series circuit of an AC coupling capacitor 443, a termination resistor 442, and an AC coupling capacitor 444 is connected between the 14-pin terminal 521 and the 19-pin terminal 522 of the HDMI terminal 101.
- a series circuit of a resistor 462 and a resistor 463 is connected between the power supply line (+5.0 V) and the ground line.
- a connection point between the resistor 462 and the resistor 463 is connected to a connection point Q4 between the 19-pin terminal 522 and the AC coupling capacitor 444 via the choke coil 461.
- connection point P3 between the AC coupling capacitor 443 and the termination resistor 442 is connected to the output side of the adder circuit 449 and to the positive input side of the LAN signal receiving circuit 445.
- a connection point P4 between the AC coupling capacitor 444 and the termination resistor 442 is connected to the output side of the adder circuit 450 and to the negative input side of the LAN signal receiving circuit 445.
- One input side of the addition circuit 449 is connected to the positive output side of the LAN signal transmission circuit 441, and the SPDIF signal output from the SPDIF transmission circuit 104 is supplied to the other input side of the addition circuit 449 via the amplifier 451. Is done. Further, one input side of the adder circuit 450 is connected to the negative output side of the LAN signal transmission circuit 441, and the SPDIF signal output from the SPDIF transmission circuit 104 is connected to the other input side of the addition circuit 450 via the amplifier 451. Supplied.
- a transmission signal (transmission data) SG417 is supplied from the Ethernet interface 115 to the input side of the LAN signal transmission circuit 441.
- the output signal SG418 of the LAN signal receiving circuit 445 is supplied to the positive terminal of the subtracting circuit 446, and the transmission signal SG417 is supplied to the negative terminal of the subtracting circuit 446.
- the transmission signal SG417 is subtracted from the output signal SG418 of the LAN signal receiving circuit 445 to obtain a reception signal (reception data) SG419.
- This reception signal SG419 becomes the LAN signal when a LAN signal (Ethernet signal) is transmitted as a differential signal via the reserved line and the HPD line.
- This reception signal SG419 is supplied to the Ethernet interface 115.
- FIG. 9 shows a configuration example of the high-speed bus interface 203a of the audio amplifier 200 in the AV system 10 of FIG.
- the Ethernet interface 210 performs LAN (Local Area Network) communication, that is, transmission and reception of an Ethernet signal, using a transmission path configured by a pair of lines of a reserved line and an HPD line among a plurality of lines constituting the HDMI cable 610.
- the SPDIF receiving circuit 204 receives the SPDIF signal using the transmission path constituted by the above-described pair of lines.
- the audio amplifier 200 includes a LAN signal transmission circuit 411, a termination resistor 412, AC coupling capacitors 413 and 414, a LAN signal reception circuit 415, a subtraction circuit 416, an addition circuit 419, and an amplifier 420. These constitute the high-speed bus interface 203a.
- the audio amplifier 200 includes a pull-down resistor 431, a resistor 432, a capacitor 433, and a comparator 434 that constitute a plug connection detection circuit 221.
- the resistor 432 and the capacitor 433 constitute a low-pass filter.
- a series circuit of an AC coupling capacitor 413, a termination resistor 412 and an AC coupling capacitor 414 is connected between the 14-pin terminal 511 and the 19-pin terminal 512 of the HDMI terminal 201a.
- a connection point P1 between the AC coupling capacitor 413 and the termination resistor 412 is connected to the positive output side of the LAN signal transmission circuit 411 and to the positive input side of the LAN signal reception circuit 415.
- connection point P2 between the AC coupling capacitor 414 and the termination resistor 412 is connected to the negative output side of the LAN signal transmission circuit 411 and to the negative input side of the LAN signal reception circuit 415.
- a transmission signal (transmission data) SG411 is supplied from the Ethernet interface 210 to the input side of the LAN signal transmission circuit 411.
- the output signal SG412 of the LAN signal receiving circuit 415 is supplied to the positive terminal of the subtraction circuit 416, and the transmission signal (transmission data) SG411 is supplied to the negative terminal of the subtraction circuit 416.
- the transmission signal SG411 is subtracted from the output signal SG412 of the LAN signal receiving circuit 415 to obtain a reception signal SG413.
- This reception signal SG413 is the LAN signal when a LAN signal (Ethernet signal) is transmitted as a differential signal via the reserve line and the HPD line.
- This reception signal SG413 is supplied to the Ethernet interface 210.
- connection point Q2 between the AC coupling capacitor 414 and the 19-pin terminal 512 is connected to the ground line through the pull-down resistor 431 and is connected to the ground line through a series circuit of the resistor 432 and the capacitor 433.
- the output signal of the low-pass filter obtained at the connection point between the resistor 432 and the capacitor 433 is supplied to one input terminal of the comparator 434.
- the output signal of the low-pass filter is compared with a reference voltage Vref2 (+1.4 V) supplied to the other input terminal.
- the output signal SG415 of the comparator 434 is supplied to a control unit (CPU) (not shown) of the audio amplifier 200.
- connection point P1 between the AC coupling capacitor 413 and the termination resistor 412 is connected to one input terminal of the adder circuit 419.
- connection point P2 between the AC coupling capacitor 414 and the termination resistor 412 is connected to the other input terminal of the adder circuit 419.
- the output signal of the adding circuit 419 is supplied to the SPDIF receiving circuit 115 via the amplifier 420.
- the output signal of the adding circuit 419 becomes the SPDIF signal when the SPDIF signal is transmitted as an in-phase signal via the reserved line and the HPD line.
- the high-speed bus interface 203b of the audio amplifier 200 has the same configuration as that of the high-speed bus interface 103 shown in FIG.
- the high-speed bus interface 303 of the BD player 300 has the same configuration as that of the high-speed bus interface 203a shown in FIG.
- FIG. 10 shows a frame configuration in the IEC 60958 standard. Each frame is composed of two subframes. In the case of two-channel stereo sound, the left channel signal is included in the first subframe, and the right channel signal is included in the second subframe.
- a preamble is provided at the head of the subframe, and “M” is assigned as the preamble to the left channel signal, and “W” is assigned as the preamble to the right channel signal.
- “B” indicating the start of a block is assigned to the leading preamble every 192 frames. That is, one block is composed of 192 frames.
- a block is a unit constituting a channel status described later.
- FIG. 11 shows a subframe configuration in the IEC 60958 standard.
- the subframe is composed of a total of 32 time slots from the 0th to the 31st.
- the 0th to 3rd time slots indicate a preamble (Sync preamble).
- This preamble indicates one of “M”, “W”, and “B” in order to distinguish the left and right channels and to indicate the start position of the block as described above.
- the 4th to 27th time slots are main data fields, and when the 24-bit code range is adopted, the whole represents audio data.
- the 8th to 27th time slots represent audio data (Audio (sample word).
- the fourth to seventh time slots can be used as additional information (Auxiliary sample bits).
- the 28th time slot is a validity flag (Validity flag) of the main data field.
- the 29th time slot represents one bit of user data (User data).
- a series of user data can be constructed by accumulating the 29th time slot across each frame.
- This user data message is configured in units of 8-bit information units (IU: Information Unit), and one message includes 3 to 129 information units.
- [0] There can be 0 to 8 bits of “0” between information units.
- the head of the information unit is identified by the start bit “1”.
- the first seven information units in the message are reserved, and the user can set arbitrary information in the eighth and subsequent information units. Messages are divided by “0” of 8 bits or more.
- the 30th time slot represents one bit of the channel status (Channel status).
- a series of channel statuses can be constructed by accumulating 30th time slots for each block across each frame.
- the head position of the block is indicated by the “B” preamble (0th to 3rd time slots) as described above.
- the 31st time slot is a parity bit. This parity bit is added so that the number of “0” and “1” included in the fourth to 31st time slots is an even number.
- FIG. 12 shows a signal modulation method in accordance with IEC 60958 standard.
- Bi-phase mark modulation is performed on the 4th to 31st time slots excluding the preamble in the subframe.
- a clock that is twice as fast as the original signal (source coding) is used. If the clock cycle of the original signal is divided into the first half and the second half, the output of the biphase mark modulation is always inverted at the edge of the first half clock cycle. Further, at the edge of the second half clock cycle, the signal is inverted when the original signal indicates “1”, and is not inverted when the original signal indicates “0”. As a result, the clock component in the original signal can be extracted from the biphase mark modulated signal.
- FIG. 13 shows channel coding of a preamble in the IEC 60958 standard.
- the fourth to 31st time slots of the subframe are biphase mark modulated.
- the preambles in the 0th to 3rd time slots are handled as bit patterns synchronized with the double speed clock, not the normal biphase mark modulation. That is, by assigning 2 bits to each time slot of the 0th to 3rd time slots, an 8-bit pattern as shown in the figure is obtained.
- FIG. 14 schematically shows the format of the channel status in the IEC 60958 standard.
- the channel status is obtained by accumulating the 30th time slot in the subframe for each block.
- the contents of the channel status are arranged one byte at a time in the vertical direction, and the bit configuration in each byte is shown in the horizontal direction.
- explanation will be made assuming a consumer-use format.
- the 0th bit (bit 0) is a bit indicating that this channel status is for consumer use.
- the first bit (bit 1) is a bit indicating whether or not it is a linear PCM sample.
- the sixth and seventh bits (bits 6-7) are fields indicating the channel status mode.
- the 0th to 3rd bits (bit 24-27) and the 6th and 7th bits (bit 30-31) are fields indicating the sampling frequency (sampling frequency).
- FIG. 15 shows the current regulation situation. This field has a reserved area as shown in the figure, and it is possible to define a new sampling frequency.
- the SPDIF signal including 2-channel audio data is performed in accordance with the above-mentioned IEC 60958 standard.
- the SPDIF signal including multi-channel audio data such as 5.1 channel, 7.1 channel, 10.2 channel, 22.2 channel can be transmitted by extending the IEC ⁇ ⁇ 60958 standard. .
- the transmission frequency is four times the sampling frequency specified in the IEC 60958 standard. This is because auxiliary information is added to audio data to be transmitted, a preamble is added, and bi-phase mark modulation is performed.
- a transmission band of 6 channels may be secured, and a transmission frequency that is three times that of normal transmission, that is, 2-channel transmission may be used.
- the sampling frequency per channel is 48 kHz
- “bit 24-27” and “bit 30” of the channel status are defined.
- a transmission band of 12 channels may be secured, and a transmission frequency that is 6 times that of normal transmission, that is, 2 channel transmission may be used.
- the sampling frequency per channel is 48 kHz
- “bit 24-27” and “bit 30” of the channel status are defined.
- -31 is assigned to the reserved area, for example
- a transmission band of 24 channels may be secured, and a transmission frequency that is 12 times that of normal transmission, that is, 2 channel transmission, may be used.
- the sampling frequency per channel is 48 kHz
- “bit 24-27” and “bit 30” of the channel status are defined.
- FIG. 16A shows the correspondence between the number of channels and the sampling frequency when the sampling frequency per channel is 48 kHz.
- the sampling frequency per channel is other than 48 kHz, for example, 44.1 kHz, 32 kHz, etc.
- sampling frequencies corresponding to 6, 12, and 24 channels can be newly defined.
- the audio data of each channel constituting the multi-channel audio data included in the SPDIF signal has a dedicated sampling frequency corresponding to the number of channels. That is, the number of channels can be recognized by the sampling frequency.
- a method may be conceived in which a pointer has the meaning of being designated in another area, and for example, a value is written in the area of “Bit 61-66” for identification. According to the method shown in FIG. 16B, the usage amount of the reserved area of “Bit 30-31” can be suppressed.
- the past receivers do not know the combination of values newly assigned to the “bit 24-27” and “bit 30-31” areas of the channel status as described above.
- the PLL does not lock, and as a result, data cannot be read and an error occurs, and the audio is muted and noise is generated. Absent.
- the specified sampling frequency is selected as an even multiple of 32 kHz, 44.1 kHz, and 48 kHz. If the transmission frequency is an even multiple of these frequencies, the PLL may lock, including pseudo-lock, but as described above, a further even multiple of the transmission frequency that is three times these frequencies is selected. This makes it possible to prevent the PLL of the past receiver from being erroneously locked.
- the channel number starts from the preamble of B, and channel 1, channel 2, channel 3,. If it is assigned and assigned so as to start from channel 1 again, the channel number on the receiving side can be identified.
- FIG. 17 shows an example of a frame configuration in 6-channel multi-channel transmission.
- 6-channel cluster (6ch) cluster is configured every 3 frames. That is, the 6-channel cluster 0 is configured by the frames 0 to 2, the 6-channel cluster 1 is configured by the frames 3 to 5, and this is repeated thereafter. In this case, channel 1 and channel 2 are assigned to frame 0, channel 3 and channel 4 are assigned to frame 1, channel 5 and channel 6 are assigned to frame 2, and so on. Although not shown, the same applies to the frame configuration in 12-channel or 24-channel multi-channel transmission.
- the channel number can be identified by the above-described assignment method, but it is also necessary to specify the position of the speaker that actually reproduces the audio data of each channel. That is, information indicating the correspondence between each channel and the speaker position is required.
- an information area indicating the correspondence between each channel and the speaker position is provided in the channel status (see FIG. 14).
- information indicating the correspondence between each channel and the speaker position is inserted in the area of “bit 67-74” of the channel status.
- 8-bit area 255 speaker positions can be specified. All 0s are not used in consideration of past compatibility.
- FIG. 18 shows an example of the correspondence between the value of “bit7467-74” and each channel and speaker position indicated by the value.
- FL, FR, FC, etc. indicating the speaker position can be identified up to 32 by referring to the IEC 62574 standard.
- a method capable of identifying up to 32 channels is illustrated in consideration of future expansion.
- “-” is present in the data slot, but does not contain valid data and indicates that it is not used for audio reproduction.
- the receiving side can supply the audio data of each channel to the corresponding speaker based on the information indicating the correspondence between each channel and the speaker position. Further, the receiving side can indicate to the user what kind of multi-channel audio has been transmitted based on this information on the display panel.
- FIG. 19 shows an example of UI display on the receiving side.
- FIG. 19A is a display when 2-channel transmission is performed
- FIG. 19B is a display when switching to 5.1 channel, that is, 6-channel transmission.
- the same display is performed in the case of other multi-channel transmissions.
- the receiving side is an audio amplifier 200
- UI display is performed on the display panel 217 (see FIG. 3).
- a similar UI display can be displayed on the transmission side.
- the transmitting side is the television receiver 100, and UI display is performed on the display panel 111 (see FIG. 2).
- an area for clearly indicating support information for these new sampling frequencies is provided, or a new descriptor is provided so that the receiver side Capabilities can be presented to the sender to improve connectivity.
- FIG. 20A shows a configuration example of a current audio short descriptor (Audio Short Descriptor).
- Fig. 20 (b) shows a configuration example of an audio short descriptor in which a region for clearly indicating support information of new sampling frequencies (576 kHz, 288 kHz, and 144 kHz) is newly defined.
- Fig. 6 shows an example of the structure of a newly created descriptor, and an area for clearly indicating support information of new sampling frequencies (576 kHz, 288 kHz, and 144 kHz) is provided.
- FIG. 21 is a flowchart showing an example of the operation of the television receiver 100 on the SPDIF signal transmission side, for example.
- audio data of 6 channels (5.1 channels) is handled.
- step ST1 the television receiver 100 acquires audio data of 6 channels (5.1 channels) and prepares for output.
- step ST2 the television receiver 100 acquires information on the audio short descriptor of the audio amplifier 200 on the receiving side.
- the television receiver 100 can acquire the information through communication using the CEC line with the audio amplifier 200.
- step ST3 the television receiver 100 determines whether 144 kHz is supported as a sampling frequency on the reception side.
- step ST4 the television receiver 100 generates an SPDIF signal including 6-channel audio data having a sampling frequency of 144 kHz, and transmits it to the audio amplifier 200 on the receiving side.
- the television receiver 100 proceeds to the process of step ST5.
- step ST5 the television receiver 100 performs a downmix process from 6 channels to 2 channels to acquire 2 channels of audio data.
- the television receiver 100 generates an SPDIF signal including 2-channel audio data having a sampling frequency of 48 kHz, and transmits the SPDIF signal to the audio amplifier 200 on the reception side.
- the television receiver 100 immediately outputs 6 channels (5.1 channels) if the receiving side supports 144 kHz.
- 2-channel output is possible by performing a downmix process. Therefore, in this case, it is also possible to display a choice of output mode on the UI and allow the user to select a desired output mode.
- FIG. 22A shows an example of UI display in that case.
- the UI display changes as shown in FIG. 22B, and the user can confirm the output mode selection.
- the television receiver 100 sends the audio amplifier 200 multi-channel audio data (such as 5.1 channel, 7.1 channel, 10.2 channel, 22.2 channel) ( SPDIF signals including linear PCM) can be transmitted.
- multi-channel audio data such as 5.1 channel, 7.1 channel, 10.2 channel, 22.2 channel
- SPDIF signals including linear PCM can be transmitted.
- the multichannel audio data included in the SPDIF signal transmitted from the television receiver 100 to the audio amplifier 200 has a sampling frequency corresponding to the number of channels and is transmitted. Information indicating the sampling frequency is added to the audio data. Therefore, the audio amplifier 200 can recognize the number of channels based on the information indicating the sampling frequency, and can perform processing of received audio data satisfactorily.
- the multi-channel audio data included in the SPDIF signal transmitted from the television receiver 100 to the audio amplifier 200 is added with information indicating the correspondence between each channel and the speaker position. Is. Therefore, the audio amplifier 200 can appropriately supply the audio data of each channel to the corresponding speaker.
- the multi-channel audio data included in the SPDIF signal has a dedicated sampling frequency corresponding to the number of channels, and the receiving side can recognize the number of channels by this dedicated sampling frequency. It has become. However, it is also conceivable that the reception side can recognize the number of channels by defining a preamble of a new bit string and changing the preamble sequence.
- FIG. 23 shows an example of a newly defined preamble.
- Each preamble pattern is a pattern having no DC component (the number of 0s is the same as the number of 1s).
- the preamble pattern of “new 1” is “11011000” if the previous state is “0”, and “00100111” if the previous state is “1”.
- the preamble pattern of “new 2” is “11011010” if the previous state is “0”, and “00100101” if the previous state is “1”.
- the preamble pattern of “new 3” is “11011100” if the previous state is “0”, and “00101011” if the previous state is “1”.
- FIG. 24 shows an example of a frame configuration in 6-channel multi-channel transmission when a newly defined preamble is used instead of the preambles “B”, “M”, and “W” as preambles.
- 6-channel cluster (6ch) cluster is configured every 3 frames. That is, the 6-channel cluster 0 is configured by the frames 0 to 2, the 6-channel cluster 1 is configured by the frames 3 to 5, and this is repeated thereafter. In this case, channel 1 and channel 2 are assigned to frame 0, channel 3 and channel 4 are assigned to frame 1, channel 5 and channel 6 are assigned to frame 2, and so on.
- the preamble of “New 1” is used for the first channel 1 of the block, and “New 2” and “New 3” are used alternately for the subsequent channels.
- the number of channels is six.
- the cluster boundary can be identified by sequentially counting the channels from the beginning of the block, and each 6-channel cluster composed of channels 1 to 6 can be grasped.
- the number of channels can be recognized on the receiving side by changing the preamble sequence in the same manner for the frame configuration in 12-channel or 24-channel multi-channel transmission.
- FIG. 25 shows an example of a frame configuration in 6-channel multi-channel transmission in that case.
- the preamble of “B” or “M” (“B” is only the beginning of the block) is used for channel 1, the “W” preamble is used for channel 2, and “new 3” is used for channel 3. ”, A“ new 2 ”preamble is used for channel 4, a“ new 3 ”preamble is used for channel 5, and a“ new 2 ”preamble is used for channel 6.
- a preamble “B” or “M” is used for each first channel 1 of the 6-channel cluster. Therefore, on the receiving side, a 6-channel cluster composed of channels 1 to 6 can be easily grasped.
- the number of channels can be recognized on the receiving side by changing the preamble sequence, it is not necessary to use a dedicated sampling frequency corresponding to the number of channels. That is, it is possible to transmit multi-channel audio data using a sampling frequency that is conventionally defined. For example, although 176.4 kHz is used as the sampling frequency, multi-channel transmission of 8 channels instead of 2 channels can be performed.
- HDMI ARC is used to transmit an SPDIF signal from the television receiver 100 to the audio amplifier 200 . That is, this is an example in which HDMI ARC is used as the IEC 60958 transmission path.
- the present technology can be similarly applied to an example in which a coaxial cable or an optical cable is used as the IEC 60958 transmission line.
- FIG. 26 shows a configuration example of the AV system 10A when an optical cable is used as the IEC 60958 transmission line.
- the television receiver 100 includes an optical interface 129
- the audio amplifier 200 includes an optical interface 222.
- the SPDIF signal output from the SPDIF transmission circuit 104 of the television receiver 100 is transmitted to the SPDIF reception circuit 204 of the audio amplifier 200 via the optical interface 129, the optical cable 630, and the optical interface 222.
- HDMI ARC is used as the IEC 60958 transmission line (see FIG. 1)
- a coaxial cable or an optical cable is used as the IEC 60958 transmission line (see FIG. 26) are mentioned.
- the SPDIF signal (IEC 60958 signal) is mapped to an audio sample packet (audio sample packet) and transmitted in the same forward direction as video transmission.
- An audio short descriptor (Audio short descriptor) in the HDMI receiver is read by the HDMI transmitter through a DDC line in the HDMI transmission path.
- a display port transmission path (DP transmission path) is used as the IEC 60958 transmission path.
- the SPDIF signal (IEC 60958 signal) is mapped to the audio sample packet (audio sample packet) and transmitted in the same forward direction as the video transmission.
- a data acquisition unit that acquires multi-channel audio data of a predetermined number of channels is provided, The multi-channel audio data has a sampling frequency corresponding to the predetermined number of channels, A data transmission unit that sequentially transmits the audio data of each channel constituting the multi-channel audio data to the reception side for each unit audio data via a predetermined transmission path; A transmission apparatus further comprising: an information addition unit that adds information indicating the sampling frequency to audio data transmitted by the data transmission unit.
- the transmission device wherein the predetermined number of channels is 6, 12, or 24.
- the information adding unit The transmission device according to (1) or (2), wherein information indicating a correspondence relationship between each channel and a speaker position is further added to the audio data transmitted by the data transmission unit.
- the data transmitter is The multi-channel audio data having the predetermined number of channels is transmitted to the receiving side when the receiving side supports a sampling frequency corresponding to the predetermined number of channels. Transmitter device.
- the transmission device further including a user interface unit that displays a channel configuration of the multi-channel audio data transmitted by the data transmission unit.
- a user interface unit that displays a channel configuration of the multi-channel audio data transmitted by the data transmission unit.
- (7) having a data acquisition step of acquiring multi-channel audio data of a predetermined number of channels;
- the multi-channel audio data has a sampling frequency corresponding to the predetermined number of channels,
- a transmission method further comprising an information addition step of adding information indicating the sampling frequency to the audio data transmitted in the data transmission step.
- a data receiving unit that sequentially receives audio data of each channel constituting multi-channel audio data of a predetermined number of channels from the transmission side for each unit audio data via a predetermined transmission path,
- the multi-channel audio data has a sampling frequency corresponding to the predetermined number of channels, Information indicating the sampling frequency is added to the audio data received by the data receiving unit,
- a receiving apparatus further comprising a processing unit that recognizes the predetermined number of channels based on information indicating the sampling frequency and processes audio data received by the data receiving unit.
- the receiving device wherein the predetermined number of channels is 6, 12, or 24.
- the receiving device according to any one of (8) to (12), further including a user interface unit that displays a channel configuration of the multi-channel audio data received by the data receiving unit.
- a data receiving step of sequentially receiving the audio data of each channel constituting the multi-channel audio data of a predetermined number of channels from the transmitting side for each unit audio data via the predetermined transmission path by the data receiving unit;
- the multi-channel audio data has a sampling frequency corresponding to the predetermined number of channels, Information indicating the sampling frequency is added to the audio data received in the data receiving step,
- a receiving method further comprising a processing step of recognizing the predetermined number of channels based on information indicating the sampling frequency and processing the audio data received in the data receiving step.
- a data acquisition unit that acquires multi-channel audio data of a predetermined number of channels;
- a data transmission unit that sequentially transmits the audio data of each channel to a reception side via a predetermined transmission path with a preamble added for each unit audio data,
- a transmitting apparatus wherein the preamble pattern added to the head unit audio data for each unit audio data of the predetermined number of continuous channels is a specific pattern indicating the head.
- the transmission device further including an information addition unit that adds information indicating a correspondence relationship between each channel and a speaker position to the audio data transmitted by the data transmission unit.
- the preamble pattern added to the head unit audio data for each continuous unit audio data of the predetermined number of channels is a specific pattern indicating the head. Transmission method.
- a data receiving unit that sequentially receives audio data of each channel constituting multi-channel audio data of a predetermined number of channels from a transmitting side via a predetermined transmission path with a preamble added for each unit audio data;
- the preamble pattern added to the head unit audio data for each continuous unit audio data of the predetermined number of channels is a specific pattern indicating the head,
- a processing unit for recognizing the predetermined number of channels based on a preamble pattern added to unit audio data sequentially received by the data receiving unit and processing the audio data received by the data receiving unit; Receiver device.
- the audio data received by the data receiving unit is further added with information indicating the correspondence between each channel and the speaker position,
- the processing unit The receiving device according to (18), wherein the audio data of each channel is supplied to a corresponding speaker based on the information indicating the correspondence relationship.
- DESCRIPTION OF SYMBOLS 10 ... AV system 100 ... Television receiver 101 ... HDMI terminal 102 ... HDMI receiving part 103 ... High speed bus interface 104 ... SPDIF transmission circuit 105 ... Antenna terminal 106 ... Digital tuner 107 ... MPEG decoder 108 ... Video signal processing circuit 109 ... Graphic generation circuit 110 ... Panel drive circuit 111 ... Display panel 112 ... Audio signal processing circuit 113 ... Audio Amplifier circuit 114 ... Speaker 115 ... Ethernet interface 116 ... Network terminal 120 ... Internal bus 121 ... CPU 122 ... Flash ROM 123 ... DRAM 124 ... Display control unit 125 ... Remote control receiving unit 126 ... Remote control transmitter 127 ... Power supply unit 128 ...
- Plug connection transmission circuit 200 ... Audio amplifiers 201a, 201b ... HDMI terminal 202a ... HDMI transmission unit 202b ... HDMI reception unit 203a, 203b ... High-speed bus interface 204 ... SPDIF reception circuit 205 ... MPEG decoder 206 ... Video / graphic processing circuit 207 ... Audio processing Circuit 208 ... Audio amplification circuit 209 ... Audio output terminal 210 ... Ethernet interface 211 ... Internal bus 212 ... CPU 213: Flash ROM 214 ... DRAM 215: Display control unit 216: Panel drive circuit 217 ... Display panel 218 ... Power supply unit 219 ... Remote control reception unit 220 ... Remote control transmitter 221 ... Plug connection detection circuit 300 ..BD player 301 ...
- HDMI terminal 302 ... HDMI transmission unit 303 ... high speed bus interface 304 ... internal bus 305 ... CPU 306 ... Flash ROM 307 ... SDRAM 308: Display control unit 309: Remote control receiving unit 310 ... Remote control transmitter 311 ... Storage medium control interface 312a ... BD drive 312b ... HDD 312c ... SSD 313: Ethernet interface 314: Network terminal 315 ... MPEG decoder 316 ... Graphic generation circuit 317 ... Video output terminal 318 ... Audio output terminal 319 ... Panel drive circuit 320 ... Display Panel 321... Power supply unit 400... Reception antenna 500 .. speaker system 610, 620... HDMI cable 630.
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Abstract
Description
所定チャネル数のマルチチャネルオーディオデータを取得するデータ取得部を備え、
上記マルチチャネルオーディオデータは、上記所定チャネル数に対応した標本化周波数を持ち、
上記マルチチャネルオーディオデータを構成する各チャネルのオーディオデータを単位オーディオデータ毎に順次所定伝送路を介して受信側に送信するデータ送信部と、
上記データ送信部で送信されるオーディオデータに上記標本化周波数を示す情報を付加する情報付加部をさらに備える
送信装置にある。
所定チャネル数のマルチチャネルオーディオデータを構成する各チャネルのオーディオデータを送信側から所定伝送路を介して単位オーディオデータ毎に順次受信するデータ受信部を備え、
上記マルチチャネルオーディオデータは上記所定チャネル数に対応した標本化周波数を持ち、
上記データ受信部で受信されるオーディオデータに上記標本化周波数を示す情報が付加されており、
上記標本化周波数を示す情報に基づいて上記所定チャネル数を認識して、上記データ受信部で受信されるオーディオデータを処理する処理部をさらに備える
受信装置にある。
所定チャネル数のマルチチャネルオーディオデータを取得するデータ取得部と、
上記各チャネルのオーディオデータを単位オーディオデータ毎にプリアンブルを付加した状態で順次所定伝送路を介して受信側に送信するデータ送信部を備え、
上記所定チャネル数の連続した単位オーディオデータ毎の先頭の単位オーディオデータに付加される上記プリアンブルのパターンは先頭を示す特定のパターンとされる
送信装置にある。
所定チャネル数のマルチチャネルオーディオデータを構成する各チャネルのオーディオデータを送信側から所定伝送路を介して単位オーディオデータ毎にプリアンブルが付加された状態で順次受信するデータ受信部を備え、
上記所定チャネル数の連続した単位オーディオデータ毎の先頭の単位オーディオデータに付加される上記プリアンブルのパターンは先頭を示す特定のパターンとされており、
上記データ受信部で順次受信される単位オーディオデータに付加されているプリアンブルのパターンに基づいて上記所定チャネル数を認識して、上記データ受信部で受信されるオーディオデータを処理する処理部をさらに備える
受信装置にある。
1.実施の形態
2.変形例
[AVシステムの構成例]
図2は、テレビ受信機100の構成例を示している。このテレビ受信機100は、HDMI端子101と、HDMI受信部102と、高速バスインタフェース103と、SPDIF(Sony Philips Digital Interface)送信回路104を有している。また、テレビ受信機100は、アンテナ端子105と、デジタルチューナ106と、MPEGデコーダ107と、映像信号処理回路108と、グラフィック生成回路109と、パネル駆動回路110と、表示パネル111とを有している。
図3は、オーディオアンプ200の構成例を示している。オーディオアンプ200は、HDMI端子201a,201bと、HDMI送信部202aと、HDMI受信部202bと、高速バスインタフェース203a,203bと、SPDIF受信回路204を有している。
図4は、BDプレーヤ300の構成例を示している。このBDプレーヤ300は、HDMI端子301と、HDMI送信部302と、高速バスインタフェース303を有している。また、このBDプレーヤ300は、内部バス304と、CPU(Central Processing Unit)305と、フラッシュROM(Read Only Memory)306と、SDRAM(Synchronous Random Access Memory)307と、表示制御部308と、リモコン受信部309と、リモコン送信機310を有している。
図5は、図1のAVシステム10における、テレビ受信機100のHDMI受信部102とオーディオアンプ200のHDMI送信部202aの構成例を示している。なお、オーディオアンプ200のHDMI受信部202bとBDプレーヤ300のHDMI送信部302の構成例に関しては、同様の構成となるので、説明は省略する。
図8は、図1のAVシステム10におけるテレビ受信機100の高速バスインタフェース103の構成例を示している。イーサネットインタフェース115は、HDMIケーブル610を構成する複数のラインのうち、リザーブラインおよびHPDラインの一対のラインにより構成された伝送路を用いてLAN(Local Area Network)通信、つまりイーサネット信号の送受信を行う。SPDIF送信回路104は、上述の一対のラインにより構成された伝送路を用いて、SPDIF信号を送信する。
最初に、IEC 60958規格の概要について説明する。図10は、IEC 60958規格におけるフレーム構成を示している。各フレームは2つのサブフレームから構成される。2チャネルステレオ音声の場合、1つ目のサブフレームに左チャネル信号が含まれ、2つ目のサブフレームに右チャネル信号が含まれる。
上述実施の形態においては、SPDIF信号に含まれるマルチチャネルオーディオデータはそのチャネル数に対応した専用標本化周波数を持つものであって、受信側では、この専用標本化周波数によりチャネル数を認識可能となっている。しかし、新たなビット列のプリアンブルを定義し、プリアンブルシーケンスを変更することで受信側においてチャネル数を認識可能とすることも考えられる。
(1)所定チャネル数のマルチチャネルオーディオデータを取得するデータ取得部を備え、
上記マルチチャネルオーディオデータは、上記所定チャネル数に対応した標本化周波数を持ち、
上記マルチチャネルオーディオデータを構成する各チャネルのオーディオデータを単位オーディオデータ毎に順次所定伝送路を介して受信側に送信するデータ送信部と、
上記データ送信部で送信されるオーディオデータに上記標本化周波数を示す情報を付加する情報付加部をさらに備える
送信装置。
(2)上記所定チャネル数は、6、12または24である
前記(1)に記載の送信装置。
(3)上記情報付加部は、
上記データ送信部で送信されるオーディオデータに上記各チャネルとスピーカポジションとの対応関係を示す情報をさらに付加する
前記(1)または(2)に記載の送信装置。
(4)受信側がサポートする標本化周波数の情報を取得する情報取得部をさらに備え、
上記データ送信部は、
上記所定チャネル数に対応した標本化周波数を上記受信側がサポートしているとき、上記所定チャネル数のマルチチャネルオーディオデータを上記受信側に送信する
前記(1)から(3)のいずれかに記載の送信装置。
(5)上記所定伝送路は、同軸ケーブル、光ケーブル、HDMIケーブルまたはディスプレイポートケーブルである
前記(1)から(4)のいずれかに記載の送信装置。
(6)上記データ送信部が送信する上記マルチチャネルオーディオデータのチャネル構成を表示するユーザインタフェース部をさらに備える
前記(1)から(5)のいずれかに記載の送信装置。
(7)所定チャネル数のマルチチャネルオーディオデータを取得するデータ取得ステップを有し、
上記マルチチャネルオーディオデータは、上記所定チャネル数に対応した標本化周波数を持ち、
データ送信部により、上記マルチチャネルオーディオデータを構成する各チャネルのオーディオデータを単位オーディオデータ毎に順次所定伝送路を介して受信側に送信するデータ送信ステップと、
上記データ送信ステップで送信されるオーディオデータに上記標本化周波数を示す情報を付加する情報付加ステップをさらに有する
送信方法。
(8)所定チャネル数のマルチチャネルオーディオデータを構成する各チャネルのオーディオデータを送信側から所定伝送路を介して単位オーディオデータ毎に順次受信するデータ受信部を備え、
上記マルチチャネルオーディオデータは上記所定チャネル数に対応した標本化周波数を持ち、
上記データ受信部で受信されるオーディオデータに上記標本化周波数を示す情報が付加されており、
上記標本化周波数を示す情報に基づいて上記所定チャネル数を認識して、上記データ受信部で受信されるオーディオデータを処理する処理部をさらに備える
受信装置。
(9)上記所定チャネル数は、6、12または24である
前記(8)に記載の受信装置。
(10)上記受信部で受信されるオーディオデータに上記各チャネルとスピーカポジションとの対応関係を示す情報がさらに付加されており、
上記処理部は、
上記対応関係を示す情報に基づいて、上記各チャネルのオーディオデータを対応するスピーカに供給する
前記(8)または(9)に記載の受信装置。
(11)サポートする標本化周波数の情報を上記送信側に送信する情報送信部をさらに備える
前記(8)から(10)のいずれかに記載の受信装置。
(12)上記所定伝送路は、同軸ケーブル、光ケーブル、HDMIケーブルまたはディスプレイポートケーブルである
前記(8)から(11)のいずれかに記載の受信装置。
(13)上記データ受信部が受信する上記マルチチャネルオーディオデータのチャネル構成を表示するユーザインタフェース部をさらに備える
前記(8)から(12)のいずれかに記載の受信装置。
(14)データ受信部により、所定チャネル数のマルチチャネルオーディオデータを構成する各チャネルのオーディオデータを送信側から所定伝送路を介して単位オーディオデータ毎に順次受信するデータ受信ステップを有し、
上記マルチチャネルオーディオデータは上記所定チャネル数に対応した標本化周波数を持ち、
上記データ受信ステップで受信されるオーディオデータに上記標本化周波数を示す情報が付加されており、
上記標本化周波数を示す情報に基づいて上記所定チャネル数を認識して、上記データ受信ステップで受信されるオーディオデータを処理する処理ステップをさらに有する
受信方法。
(15)所定チャネル数のマルチチャネルオーディオデータを取得するデータ取得部と、
上記各チャネルのオーディオデータを単位オーディオデータ毎にプリアンブルを付加した状態で順次所定伝送路を介して受信側に送信するデータ送信部を備え、
上記所定チャネル数の連続した単位オーディオデータ毎の先頭の単位オーディオデータに付加される上記プリアンブルのパターンを先頭を示す特定のパターンとする
送信装置。
(16)上記データ送信部で送信されるオーディオデータに上記各チャネルとスピーカポジションとの対応関係を示す情報を付加する情報付加部をさらに備える
前記(15)に記載の送信装置。
(17)所定チャネル数のマルチチャネルオーディオデータを取得するデータ取得ステップと、
データ送信部により、上記各チャネルのオーディオデータを単位オーディオデータ毎にプリアンブルを付加した状態で順次所定伝送路を介して受信側に送信するデータ送信ステップを有し、
上記所定チャネル数の連続した単位オーディオデータ毎の先頭の単位オーディオデータに付加される上記プリアンブルのパターンは先頭を示す特定のパターンとされる
送信方法。
(18)所定チャネル数のマルチチャネルオーディオデータを構成する各チャネルのオーディオデータを送信側から所定伝送路を介して単位オーディオデータ毎にプリアンブルが付加された状態で順次受信するデータ受信部を備え、
上記所定チャネル数の連続した単位オーディオデータ毎の先頭の単位オーディオデータに付加される上記プリアンブルのパターンは先頭を示す特定のパターンとされており、
上記データ受信部で順次受信される単位オーディオデータに付加されているプリアンブルのパターンに基づいて上記所定チャネル数を認識して、上記データ受信部で受信されるオーディオデータを処理する処理部をさらに備える
受信装置。
(19)上記データ受信部で受信されるオーディオデータには上記各チャネルとスピーカポジションとの対応関係を示す情報がさらに付加されており、
上記処理部は、
上記対応関係を示す情報に基づいて、上記各チャネルのオーディオデータを対応するスピーカに供給する
前記(18)に記載の受信装置。
(20)受信部により、所定チャネル数のマルチチャネルオーディオデータを構成する各チャネルのオーディオデータを送信側から所定伝送路を介して単位オーディオデータ毎にプリアンブルが付加された状態で順次受信するデータ受信ステップを有し、
上記所定チャネル数の連続した単位オーディオデータ毎の先頭の単位オーディオデータに付加される上記プリアンブルのパターンは先頭を示す特定のパターンとされており、
上記データ受信ステップで順次受信される単位オーディオデータに付加されているプリアンブルのパターンに基づいて上記所定チャネル数を認識して、上記データ受信ステップで受信されるオーディオデータを処理する処理ステップをさらに有する
受信方法。
100・・・テレビ受信機
101・・・HDMI端子
102・・・HDMI受信部
103・・・高速バスインタフェース
104・・・SPDIF送信回路
105・・・アンテナ端子
106・・・デジタルチューナ
107・・・MPEGデコーダ
108・・・映像信号処理回路
109・・・グラフィック生成回路
110・・・パネル駆動回路
111・・・表示パネル
112・・・音声信号処理回路
113・・・音声増幅回路
114・・・スピーカ
115・・・イーサネットインタフェース
116・・・ネットワーク端子
120・・・内部バス
121・・・CPU
122・・・フラッシュROM
123・・・DRAM
124・・・表示制御部
125・・・リモコン受信部
126・・・リモコン送信機
127・・・電源部
128・・・プラグ接続伝達回路
200・・・オーディオアンプ
201a,201b・・・HDMI端子
202a・・・HDMI送信部
202b・・・HDMI受信部
203a、203b・・・高速バスインタフェース
204・・・SPDIF受信回路
205・・・MPEGデコーダ
206・・・映像・グラフィック処理回路
207・・・音声処理回路
208・・・音声増幅回路
209・・・音声出力端子
210・・・イーサネットインタフェース
211・・・内部バス
212・・・CPU
213・・・フラッシュROM
214・・・DRAM
215・・・表示制御部
216・・・パネル駆動回路
217・・・表示パネル
218・・・電源部
219・・・リモコン受信部
220・・・リモコン送信機
221・・・プラグ接続検出回路
300・・・BDプレーヤ
301・・・HDMI端子
302・・・HDMI送信部
303・・・高速バスインタフェース
304・・・内部バス
305・・・CPU
306・・・フラッシュROM
307・・・SDRAM
308・・・表示制御部
309・・・リモコン受信部
310・・・リモコン送信機
311・・・記憶媒体制御インタフェース
312a・・・BDドライブ
312b・・・HDD
312c・・・SSD
313・・イーサネットインタフェース
314・・・ネットワーク端子
315・・・MPEGデコーダ
316・・・グラフィック生成回路
317・・・映像出力端子
318・・・音声出力端子
319・・・パネル駆動回路
320・・・表示パネル
321・・・電源部
400・・・受信アンテナ
500・・・スピーカシステム
610,620・・・HDMIケーブル
630・・・光ケーブル
Claims (20)
- 所定チャネル数のマルチチャネルオーディオデータを取得するデータ取得部を備え、
上記マルチチャネルオーディオデータは、上記所定チャネル数に対応した標本化周波数を持ち、
上記マルチチャネルオーディオデータを構成する各チャネルのオーディオデータを単位オーディオデータ毎に順次所定伝送路を介して受信側に送信するデータ送信部と、
上記データ送信部で送信されるオーディオデータに上記標本化周波数を示す情報を付加する情報付加部をさらに備える
送信装置。 - 上記所定チャネル数は、6、12または24である
請求項1に記載の送信装置。 - 上記情報付加部は、
上記データ送信部で送信されるオーディオデータに上記各チャネルとスピーカポジションとの対応関係を示す情報をさらに付加する
請求項1に記載の送信装置。 - 受信側がサポートする標本化周波数の情報を取得する情報取得部をさらに備え、
上記データ送信部は、
上記所定チャネル数に対応した標本化周波数を上記受信側がサポートしているとき、上記所定チャネル数のマルチチャネルオーディオデータを上記受信側に送信する
請求項1に記載の送信装置。 - 上記所定伝送路は、同軸ケーブル、光ケーブル、HDMIケーブルまたはディスプレイポートケーブルである
請求項1に記載の送信装置。 - 上記データ送信部が送信する上記マルチチャネルオーディオデータのチャネル構成を表示するユーザインタフェース部をさらに備える
請求項1に記載の送信装置。 - 所定チャネル数のマルチチャネルオーディオデータを取得するデータ取得ステップを有し、
上記マルチチャネルオーディオデータは、上記所定チャネル数に対応した標本化周波数を持ち、
データ送信部により、上記マルチチャネルオーディオデータを構成する各チャネルのオーディオデータを単位オーディオデータ毎に順次所定伝送路を介して受信側に送信するデータ送信ステップと、
上記データ送信ステップで送信されるオーディオデータに上記標本化周波数を示す情報を付加する情報付加ステップをさらに有する
送信方法。 - 所定チャネル数のマルチチャネルオーディオデータを構成する各チャネルのオーディオデータを送信側から所定伝送路を介して単位オーディオデータ毎に順次受信するデータ受信部を備え、
上記マルチチャネルオーディオデータは上記所定チャネル数に対応した標本化周波数を持ち、
上記データ受信部で受信されるオーディオデータに上記標本化周波数を示す情報が付加されており、
上記標本化周波数を示す情報に基づいて上記所定チャネル数を認識して、上記データ受信部で受信されるオーディオデータを処理する処理部をさらに備える
受信装置。 - 上記所定チャネル数は、6、12または24である
請求項8に記載の受信装置。 - 上記データ受信部で受信されるオーディオデータに上記各チャネルとスピーカポジションとの対応関係を示す情報がさらに付加されており、
上記処理部は、
上記対応関係を示す情報に基づいて、上記各チャネルのオーディオデータを対応するスピーカに供給する
請求項8に記載の受信装置。 - サポートする標本化周波数の情報を上記送信側に送信する情報送信部をさらに備える
請求項8に記載の受信装置。 - 上記所定伝送路は、同軸ケーブル、光ケーブル、HDMIケーブルまたはディスプレイポートケーブルである
請求項8に記載の受信装置。 - 上記データ受信部が受信する上記マルチチャネルオーディオデータのチャネル構成を表示するユーザインタフェース部をさらに備える
請求項8に記載の受信装置。 - データ受信部により、所定チャネル数のマルチチャネルオーディオデータを構成する各チャネルのオーディオデータを送信側から所定伝送路を介して単位オーディオデータ毎に順次受信するデータ受信ステップを有し、
上記マルチチャネルオーディオデータは上記所定チャネル数に対応した標本化周波数を持ち、
上記データ受信ステップで受信されるオーディオデータに上記標本化周波数を示す情報が付加されており、
上記標本化周波数を示す情報に基づいて上記所定チャネル数を認識して、上記データ受信ステップで受信されるオーディオデータを処理する処理ステップをさらに有する
受信方法。 - 所定チャネル数のマルチチャネルオーディオデータを取得するデータ取得部と、
上記各チャネルのオーディオデータを単位オーディオデータ毎にプリアンブルを付加した状態で順次所定伝送路を介して受信側に送信するデータ送信部を備え、
上記所定チャネル数の連続した単位オーディオデータ毎の先頭の単位オーディオデータに付加される上記プリアンブルのパターンを先頭を示す特定のパターンとする
送信装置。 - 上記データ送信部で送信されるオーディオデータに上記各チャネルとスピーカポジションとの対応関係を示す情報を付加する情報付加部をさらに備える
請求項15に記載の送信装置。 - 所定チャネル数のマルチチャネルオーディオデータを取得するデータ取得ステップと、
データ送信部により、上記各チャネルのオーディオデータを単位オーディオデータ毎にプリアンブルを付加した状態で順次所定伝送路を介して受信側に送信するデータ送信ステップを有し、
上記所定チャネル数の連続した単位オーディオデータ毎の先頭の単位オーディオデータに付加される上記プリアンブルのパターンは先頭を示す特定のパターンとされる
送信方法。 - 所定チャネル数のマルチチャネルオーディオデータを構成する各チャネルのオーディオデータを送信側から所定伝送路を介して単位オーディオデータ毎にプリアンブルが付加された状態で順次受信するデータ受信部を備え、
上記所定チャネル数の連続した単位オーディオデータ毎の先頭の単位オーディオデータに付加される上記プリアンブルのパターンは先頭を示す特定のパターンとされており、
上記データ受信部で順次受信される単位オーディオデータに付加されているプリアンブルのパターンに基づいて上記所定チャネル数を認識して、上記データ受信部で受信されるオーディオデータを処理する処理部をさらに備える
受信装置。 - 上記データ受信部で受信されるオーディオデータには上記各チャネルとスピーカポジションとの対応関係を示す情報がさらに付加されており、
上記処理部は、
上記対応関係を示す情報に基づいて、上記各チャネルのオーディオデータを対応するスピーカに供給する
請求項18に記載の受信装置。 - 受信部により、所定チャネル数のマルチチャネルオーディオデータを構成する各チャネルのオーディオデータを送信側から所定伝送路を介して単位オーディオデータ毎にプリアンブルが付加された状態で順次受信するデータ受信ステップを有し、
上記所定チャネル数の連続した単位オーディオデータ毎の先頭の単位オーディオデータに付加される上記プリアンブルのパターンは先頭を示す特定のパターンとされており、
上記データ受信ステップで順次受信される単位オーディオデータに付加されているプリアンブルのパターンに基づいて上記所定チャネル数を認識して、上記データ受信ステップで受信されるオーディオデータを処理する処理ステップをさらに有する
受信方法。
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