JP2009022059A - Av apparatus and interface system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an AV apparatus having a function which can reproduce at least either one of image and audio, and which enables an electronic apparatus used as a transmitting side to readily judge whether the AV apparatus itself is set up by a user so as not to be used for listening the audio to simplify handling by the user. <P>SOLUTION: This AV apparatus is provided with receiving means (16, 28) for receiving digital image signals and digital audio signals, storage means (23, 35) for storing information to the effect when the audio is set in mute state, and control means (22, 34) for outputting the information stored in the storage means (23, 35) to the outside. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an AV apparatus that transmits or receives signals such as video and audio to an externally connected electronic device. The present invention also relates to an interface system for connecting a plurality of the AV devices described above.

  As is well known, the DVI (digital visual interface) standard is widely used as a standard for transmitting digital video signals. In recent years, the high definition multimedia interface (HDMI) standard has been adopted as a digital signal transmission standard that further improves the DVI standard.

  In the HDMI standard, for example, it is possible to multiplex a digital audio signal during a blanking period of the digital video signal and perform audio transmission, in addition to transmitting the digital video signal in the form of an RGB signal, a YCbCr signal Can be transmitted in the form of a YPbPr signal of higher quality or higher, and can be connected with a USB (universal serial bus) -like small HDMI connector, etc. Is included.

  Further, in the VDI standard or the HDMI standard, when a signal such as video or audio is transmitted from one electronic device to the other electronic device, the electronic device on the transmission side receives the EDID (extended display identification data) from the electronic device on the reception side. ) Can be output in a form that matches the reception specifications of the display of the electronic device on the receiving side.

  Further, in the DVI standard and the HDMI standard, a plurality of signal output ports are installed in an electronic device that is a transmission side, and an electronic device that is a reception side is connected to each signal output port. It is possible to simultaneously transmit the same signal or a signal in another format obtained by signal conversion to a plurality of electronic devices on the receiving side. Accordingly, it is possible to realize a usage mode in which only the video is displayed on the first electronic device on the receiving side and only the audio is reproduced on the second electronic device on the receiving side.

  For example, when the HDMI standard is adopted, an optical disk playback device that plays back an optical disk such as a DVD (digital versatile disk) is assumed as an electronic device on the transmission side, and a large-screen high-definition display is used as a plurality of electronic devices on the reception side. Assuming a television receiver with a 2-channel stereo speaker and an AV (audio video) amplifier with a 5.1-channel audio playback function, the television receiver displays video with high image quality, It is possible to use in such a manner that audio reproduction with high sound quality is performed by an AV amplifier.

  By the way, in order to realize the above usage pattern, it is necessary to synchronize the display video by the television receiver and the reproduced audio by the AV amplifier. In this case, the time required for processing the video signal and the audio signal is recorded as the EDID data in the television receiver and the AV amplifier, respectively.

  For this reason, the optical disk reproducing apparatus acquires EDID data from the television receiver and the AV amplifier, respectively, and uses the time required for the video signal processing of the television receiver and the time required for the audio signal processing of the AV amplifier for display. It is possible to control the video and the reproduced audio to be synchronized.

  However, at present, in order to perform such synchronization control, a user performs video display on an electronic device connected to which signal output port with respect to an optical disc playback apparatus that is an electronic device on the transmission side. It is necessary to make an input setting as to which electronic device connected to which signal output port performs audio reproduction, and handling is complicated.

  In Patent Document 1, when a plurality of receiving devices are connected to a transmitting device and video and audio data compliant with the HDMI standard are transmitted, reception that enables video and audio reproduction based on EDID data acquired from the receiving device is disclosed. A configuration is disclosed in which video and audio data are transmitted to a device, only video data is transmitted to a receiving device that can only reproduce video, and only audio data is transmitted to a receiving device that can only reproduce audio. Has been.

  In Patent Document 2, a tuner, a recording / playback apparatus, and a monitor are connected in cascade, and the video signal specification can be requested from the video signal receiving side to the sending side. A configuration is disclosed in which when a device is in a stop mode, a video signal output from a tuner is directly transmitted to a monitor.

  Further, Patent Document 3 discloses IEEE 1394 as a standard for connecting AV devices, and a DVD player, a TV monitor, and an AV amplifier are connected to each other, and processing delay information for video display processing of the TV monitor. And means for obtaining the information by the AV amplifier and adjusting the audio delay.

Further, Patent Document 4 shows the HDMI standard as a standard for coupling between AV devices, and a video monitor and an AV amplifier, an AV amplifier and a DVD player are coupled to each other, and the video display processing delay of the monitor. Means for obtaining time and means for delaying the audio signal are described.
JP-A-2005-57714 JP 2006-19857 JP 2002-344898 JP 2006-33436 A

  Therefore, the present invention has been made in consideration of the above circumstances and has a function capable of reproducing at least one of video and audio, and is set by the user so that the user does not listen to the audio. It is an object of the present invention to provide an AV device that makes it possible for an electronic device on the transmission side to easily determine whether or not a user is easily handled.

  In addition, the present invention automatically determines whether or not each receiving electronic device connected to itself is set by the user so as not to listen to audio, and each receiving electronic device It is an object of the present invention to provide an AV apparatus that can make the handling of the user convenient by performing processing corresponding to the determination result on the video signal and the audio signal given to the user.

  Further, according to the present invention, the AV device on the transmission side automatically determines whether each AV device on the reception side is set by the user so as not to listen to the sound, and each of the AV devices on the reception side It is an object of the present invention to provide an interface system that makes it easy for a user to handle a video signal and an audio signal given to an AV apparatus by performing processing corresponding to the determination result.

  An AV apparatus according to the present invention includes a receiving unit that receives a digital video signal and a digital audio signal, a storage unit that stores information indicating that the audio is set to a mute state, and a storage unit that stores the information. And a control means for outputting information to the outside.

  In addition, the AV apparatus according to the present invention acquires transmission information for transmitting digital video signals and digital audio signals to a plurality of electronic devices, and information indicating that the sound is set to a mute state from the plurality of electronic devices. And a setting state for each audio mute of each of the plurality of electronic devices based on the information acquired by the acquisition means and the determination result on at least one of the digital video signal and the digital audio signal transmitted by the transmission means And a control means for performing predetermined signal processing corresponding to the above.

  Further, the interface system according to the present invention includes a first means for storing information indicating that to a first AV device in which audio is set to a mute state among a plurality of first AV devices, The information stored in the first AV device by the first means is transmitted to the second AV device that transmits the digital video signal and the digital audio signal to the first AV device for video display or audio reproduction. Based on the second means to be acquired and the information acquired by the second means, the setting state of the audio mute of each of the plurality of first AV devices is determined, and the digital transmitted from the second AV device And a third means for performing predetermined signal processing corresponding to the determination result on at least one of the video signal and the digital audio signal.

  In addition, the interface system according to the present invention includes a first means for storing information indicating that to a first AV device in which audio is set to a mute state among a plurality of first AV devices, The information stored in the first AV device by the first means is transmitted to the second AV device that transmits the digital video signal and the digital audio signal to the first AV device for video display or audio reproduction. Based on the second means to be acquired and the information acquired by the second means, the setting state for the audio mute of each of the plurality of first AV devices is determined, and the digital video signal and the second AV device are sent to the second AV device. The information obtained by the third AV device that transmits the digital audio signal is provided with third means for performing predetermined information processing corresponding to the determination result.

  According to the above-described invention, it is possible for the AV apparatus on the transmission side to automatically determine whether or not each AV apparatus on the reception side is set by the user so as not to listen to audio. As a result, processing corresponding to the determination result can be performed on the video signal and the audio signal to be given to each AV apparatus on the receiving side, and the handling of the user can be made convenient.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 shows the overall configuration of a signal transmission system compliant with the HDMI standard described in this embodiment. That is, in FIG. 1, reference numeral 11 denotes an optical disk reproducing apparatus. The optical disc playback apparatus 11 is an AV apparatus on the transmission side in the signal transmission system.

  The optical disk reproducing device 11 reads data recorded on an optical disk such as a DVD and reproduces digital video signals and audio signals. The digital video signal and audio signal reproduced by the optical disc reproducing apparatus 11 are converted into digital data in a form compliant with the HDMI standard, and a plurality of (two in the illustrated case) AV apparatuses on the receiving side. Is output.

  In this embodiment, as two AV devices on the receiving side, a television receiver 12 having a flat panel display capable of displaying a high-definition video on a large screen and capable of reproducing audio of two stereo channels, For example, an AV amplifier 13 having a multi-channel high-quality sound reproduction function such as 5.1 channel and capable of displaying a video on a small screen is illustrated.

  FIG. 2 shows a signal processing system of the television receiver 12. In FIG. 2, the description of the configuration of the portion that receives a television broadcast signal, selects a channel, and demodulates is omitted for the sake of simplicity. That is, the digital data output from the optical disc playback apparatus 11 in a form compliant with the HDMI standard is supplied to the input terminal 15 of the television receiver 12 via the TMDS signal transmission path 14.

  The digital data supplied to the input terminal 15 is supplied to the HDMI receiving unit 16 and separated into a digital video signal and an audio signal. Among these, the digital video signal is supplied to the video processing unit 18 constituting the playback unit 17 and subjected to predetermined video signal processing, and then displayed on the flat panel display 19.

  The digital audio signal separated by the HDMI receiving unit 16 is supplied to the audio processing unit 20 constituting the reproduction unit 17 and subjected to predetermined audio signal processing, and then the speaker 21 corresponding to stereo 2 channels. Is played back.

  In the HDMI receiving unit 16, if the separated digital audio signal includes adjustment delay data CDL (control delay), which will be described later, the digital audio signal is processed for the time specified by the adjustment delay data CDL. It has a function to output with a delay.

  In the television receiver 12, all operations including the above-described reproduction operation are controlled by the control unit 22 in an integrated manner. The control unit 22 includes a CPU (central processing unit) 22a, receives operation information from the operation unit 22b, and controls each unit so that the operation content is reflected.

  In this case, the control unit 22 uses the memory unit 22c. The memory unit 22c mainly stores a ROM (read only memory) that stores a control program executed by the CPU 22a, a RAM (random access memory) that provides a work area for the CPU 22a, and various setting information and control information. A non-volatile memory.

  The control unit 22 is connected to the EDID memory 23. In the EDID memory 23, in addition to information indicating the reception specification (video display capability / audio reproduction / display capability) of the television receiver 12, time information indicating the time VD1 required for video signal processing in the video processing unit 18 VD1D, time information AD1D indicating time AD1 required for audio signal processing in the audio processing unit 20, and the like are recorded as EDID.

  Here, when the user operates the operation unit 22b to set, for example, the video mute state, that is, when the user sets the video display on the flat panel display 19 to stop, the control unit 22 is a television. Information indicating that the receiver 12 is set in a state in which the image is not visually recognized is written in the EDID memory 23.

  Writing information in the EDID memory 23 that indicates that the television receiver 12 has been set to a state in which video is not visually recognized is time information indicating the time VD1 required for the video signal processing in the video processing unit 18. This is easily realized by rewriting VD1D to a value that cannot normally be taken, for example, “0”.

  The control unit 22 operates when the user operates the operation unit 22b to set, for example, the audio mute state, that is, when the user sets the audio reproduction on the speaker 21 to be stopped. Is written in the EDID memory 23 to indicate that it has been set not to be used for listening to audio.

  Writing into the EDID memory 23 information indicating that the television receiver 12 is not set to listen to sound is time information indicating the time AD1 required for sound signal processing in the sound processing unit 20. This is easily realized by rewriting AD1D to a value that cannot normally be taken, for example, “0”.

  That is, the time VD1 required for the video signal processing in the video processing unit 18 and the time AD1 required for the audio signal processing in the audio processing unit 20 are normally stored in the EDID memory 23 in units of 1 msec, for example, and at least 1 msec. Therefore, it cannot be “0”. For this reason, the time information VD1D and AD1D being “0” can be defined as a value that cannot be taken normally.

  For example, in a system in which it is known in advance that the times VD1 and AD1 do not become 5 msec or less, it is possible to define 5 msec or less as a value that cannot be taken normally.

  Various kinds of information stored in the EDID memory 23 are read from the EDID memory 23 in response to a request from the optical disc playback apparatus 11 which is an AV apparatus on the transmission side, and output terminals 24 and a display data channel (DDC) communication channel. 25 is transmitted to the optical disc playback apparatus 11 via

  For this reason, in the optical disc playback apparatus 11, information is acquired from the EDID memory 23 of the television receiver 12, and the time information VD1D indicating the time VD1 required for the video signal processing in the video processing unit 18 is “0”. Thus, it can be easily identified that the television receiver 12 is set to a state where the television receiver 12 is not visually recognized.

  Further, in the optical disc playback apparatus 11, information is acquired from the EDID memory 23 of the television receiver 12, and the time information AD1D indicating the time AD1 required for the audio signal processing in the audio processing unit 20 is “0”. Thus, it can be easily identified that the television receiver 12 is set to a state where it is not used for listening to audio.

  FIG. 3 shows a flowchart summarizing the operation of rewriting the time information VD1D and AD1D of the EDID memory 23 in the television receiver 12 described above. That is, when the process is started (step S1), the control unit 22 determines whether or not the main power of the television receiver 12 is turned on in step S2, and determines that the main power is not turned on. If NO (NO), the process is terminated (step S9).

  If it is determined in step S2 that the main power supply has been turned on (YES), the control unit 22 determines whether or not the video mute state has been set by the user in step S3. If it is determined that the video mute state is set (YES), the control unit 22 indicates the time VD1 required for the video signal processing in the video processing unit 18 stored in the EDID memory 23 in step S4. The time information VD1D is set to “0”.

  On the other hand, if it is determined in step S3 that the video mute state is not set (NO), the control unit 22 performs video signal processing in the video processing unit 18 stored in the EDID memory 23 in step S5. The time information VD1D indicating the time VD1 required for is set to the original value.

  After step S4 or S5, the control unit 22 determines whether or not the audio mute state has been set by the user in step S6. If it is determined that the audio mute state is set (YES), the control unit 22 indicates the time AD1 required for the audio signal processing in the audio processing unit 20 stored in the EDID memory 23 in step S7. The time information AD1D is set to “0”, and the process returns to step S2.

  If it is determined in step S6 that the audio mute state is not set (NO), the control unit 22 performs audio signal processing in the audio processing unit 20 stored in the EDID memory 23 in step S8. The time information AD1D indicating the time AD1 required for is set to the original value, and the process returns to step S2.

  According to the television receiver 12 serving as the AV apparatus on the receiving side described above, when the video mute state is set by the user, the time VD1 stored in the EDID memory 23 and required for the video signal processing in the video processing unit 18 When the time information VD1D indicating “0” is set and the sound mute state is set by the user, the time information AD1D indicating the time AD1 required for the sound signal processing in the sound processing unit 20 stored in the EDID memory 23 Is set to “0”.

  For this reason, the television receiver 12 causes the optical disc playback apparatus 11 which is the AV apparatus on the transmission side to acquire the time information VD1D and AD1D stored in the EDID memory 23, so that the television receiver 12 displays the video information. Alternatively, it can be easily identified that the state is set not to be used for audio viewing.

  Note that the television receiver 12 is not only set to the audio mute state when the audio mute key of the operation unit 22b is operated, but the volume control operator of the operation unit 22b is set to the position corresponding to the minimum volume. Even when narrowed down to, the audio mute state is set. In other words, the above expression, which is expressed as video muting or audio muting, means a state where the video is not mainly provided for viewing.

  FIG. 4 shows a signal processing system of the AV amplifier 13. That is, the digital data output from the optical disc playback apparatus 11 in a form compliant with the HDMI standard is supplied to the input terminal 27 of the AV amplifier 13 via the TMDS signal transmission path 26.

  The digital data supplied to the input terminal 27 is supplied to the HDMI receiving unit 28 and separated into a digital video signal and an audio signal. Among these, the digital video signal is supplied to the video processing unit 30 constituting the playback unit 29 and subjected to predetermined video signal processing, and then displayed on the small screen display 31.

  The digital audio signal separated by the HDMI receiving unit 28 is supplied to the audio processing unit 32 constituting the reproducing unit 29 and subjected to predetermined audio signal processing, and then a speaker corresponding to 5.1 channel. At 33, the sound is reproduced.

  When the separated digital audio signal includes adjustment delay data CDL, which will be described later, the HDMI reception unit 28 outputs the digital audio signal after being delayed by a time designated by the adjustment delay data CDL. It has a function to do.

  The AV amplifier 13 controls all the operations including the above-described reproduction operation by the control unit 34. The control unit 34 has a built-in CPU 34a, and controls each unit based on operation information from the operation unit 34b so that the operation content is reflected.

  In this case, the control unit 34 uses the memory unit 34c. The memory unit 34c mainly includes a ROM that stores a control program executed by the CPU 34a, a RAM that provides a work area for the CPU 34a, and a nonvolatile memory that stores various setting information and control information. .

  The control unit 34 is connected to the EDID memory 35. In the EDID memory 23, in addition to information indicating the reception specifications (video display capability / audio playback capability) of the AV amplifier 13, time information VD2D indicating time VD2 required for video signal processing in the video processing unit 30, audio processing Time information AD2D indicating time AD2 required for the audio signal processing in the unit 32 is recorded as EDID.

  Here, when the user operates the operation unit 34b to set the video mute state, for example, when the user sets the video amplifier on the display 31 to stop the video display, the control unit 34 causes the AV amplifier 13 to operate. Information indicating that the state is set not to be visually recognized (actually, the video may be displayed but the user is mainly watching the television receiver 12) is written in the EDID memory 35. I am doing so.

  Writing information in the EDID memory 35 that indicates that the AV amplifier 13 is set in a state in which the AV amplifier 13 is not visually recognized is time information VD2D indicating time VD2 required for video signal processing in the video processing unit 30. This is easily realized by rewriting to a value that cannot normally be taken, for example, “0”.

  Further, the control unit 34 operates when the user operates the operation unit 34b to set, for example, a sound mute state, that is, when the user sets the state to stop sound reproduction on the speaker 33, the AV amplifier 13 performs sound The information indicating that the state is set not to be listened to is written in the EDID memory 35.

  Writing into the EDID memory 35 information indicating that the AV amplifier 13 has been set not to listen to audio results in time information AD2D indicating time AD2 required for audio signal processing in the audio processing unit 32. This is easily realized by rewriting to a value that cannot normally be taken, for example, “0”.

  That is, the time VD2 required for the video signal processing in the video processing unit 30 and the time AD2 required for the audio signal processing in the audio processing unit 32 are normally stored in the EDID memory 35 in units of 1 msec, for example, and at least 1 msec. Therefore, it cannot be “0”. For this reason, the time information VD2D and AD2D being “0” can be defined as a value that cannot be taken normally.

  For example, in a system in which it is known in advance that the times VD2 and AD2 are not 5 msec or less, it is possible to define 5 msec or less as a value that cannot normally be taken.

  Various types of information stored in the EDID memory 35 are read from the EDID memory 35 in response to a request from the optical disc playback apparatus 11 which is an AV apparatus on the transmission side, and are output via the output terminal 36 and the DDC communication path 37. It is transmitted to the optical disk playback device 11.

  For this reason, in the optical disc playback apparatus 11, information is acquired from the EDID memory 35 of the AV amplifier 13, and the time information VD2D indicating the time VD2 required for the video signal processing in the video processing unit 30 is “0”. Thus, it can be easily identified that the AV amplifier 13 is set to a state in which the AV amplifier 13 is not visually recognized.

  Further, in the optical disc playback apparatus 11, information is acquired from the EDID memory 35 of the AV amplifier 13, and the time information AD2D indicating the time AD2 required for the audio signal processing in the audio processing unit 32 is “0”. It can be easily identified that the AV amplifier 13 is set in a state where it is not used for listening to audio.

  According to the AV amplifier 13 serving as the receiving-side AV device described above, when the video mute state is set by the user, the time VD2 required for the video signal processing in the video processing unit 30 stored in the EDID memory 35 is shown. When the time information VD2D is set to “0” and the audio mute state is set by the user, the time information AD2D indicating the time AD2 required for the audio signal processing in the audio processing unit 32 stored in the EDID memory 35 is set to “ It is set to 0 ”.

  For this reason, the AV amplifier 13 causes the optical amplifier playback apparatus 11 that is the AV apparatus on the transmission side to acquire the time information VD2D and AD2D stored in the EDID memory 35, so that the AV amplifier 13 can view video or audio. It can be easily identified that it is set in a state where it is not used.

  Note that the AV amplifier 13 is not only set to the audio mute state when the audio mute key of the operation unit 34b is operated, but also narrows the volume control operator of the operation unit 34b to a position corresponding to the minimum volume. In this case, the audio mute state is set. Alternatively, the audio mute state is set even when the user is set to listen with headphones and the user does not mainly display video.

  FIG. 5 shows a signal processing system of the optical disc playback apparatus 11. That is, an optical disk 38 such as a DVD is mounted on a disk drive unit 40 constituting a disk reproducing unit 39, and data recorded therein is read. The data read by the disk drive unit 40 is supplied to the video decoding unit 41 and the audio decoding unit 42, respectively.

  Among these, the video decoding unit 41 generates a digital video signal by extracting a video component from the input data and performing a decoding process. The voice decoding unit 42 generates a digital voice signal by extracting a voice component from the input data and performing a decoding process.

  The digital audio signal generated by the audio decoding unit 42 is supplied to the delay adjustment unit 43 and subjected to a predetermined amount of delay processing described later. The delay adjustment unit 43 adjusts the amount of delay when performing delay processing on the input digital audio signal.

  Here, the digital video signal generated by the video decoding unit 41 is supplied to one input terminal of each of the two HDMI transmission units 44 and 45. At the other input end of the HDMI transmitting unit 44, a digital audio signal output from the audio decoding unit 42 and a digital audio signal output from the delay adjustment unit 43 constitute a selection unit 46. 47 is selectively supplied.

  In addition, the other input terminal of the HDMI transmission unit 45 has a switch that configures the selection unit 46 with the digital audio signal output from the audio decoding unit 42 and the digital audio signal output from the delay adjustment unit 43. 48 is selectively supplied.

  The HDMI transmission unit 44 temporally multiplexes the input digital video signal and audio signal, converts the digital video signal and audio signal into digital data conforming to the HDMI standard, and outputs the output terminals 49a and 49 of the input / output port 49. The signal is output to the television receiver 12 via the TMDS signal transmission line 14.

  Further, the HDMI transmission unit 45 temporally multiplexes the input digital video signal and audio signal, converts them into digital data conforming to the HDMI standard, and outputs the output terminals 50 a and 50 of the input / output port 50. The signal is output to the AV amplifier 13 via the TMDS signal transmission path 26.

  In the optical disc playback apparatus 11, all operations including the above-described playback operation are controlled by the control unit 51 in an integrated manner. The control unit 51 has a built-in CPU 51a, and controls each unit based on operation information from the operation unit 51b so that the operation content is reflected.

  In this case, the control unit 51 uses the memory unit 51c. The memory unit 51c mainly includes a ROM that stores a control program executed by the CPU 51a, a RAM that provides a work area for the CPU 51a, and a non-volatile memory that stores various setting information and control information. .

  The control unit 51 is connected to the DDC communication path 25 for transmitting information read from the EDID memory 23 of the television receiver 12 via the input terminal 49 b of the input / output port 49. Further, the control unit 51 is connected to a DDC communication path 37 for transmitting information read from the EDID memory 35 of the AV amplifier 13 via the input terminal 50 b of the input / output port 50.

  As a result, the control unit 51 can acquire the information stored in the EDID memory 23 of the television receiver 12 and the information stored in the EDID memory 35 of the AV amplifier 13.

  FIG. 6 shows an AV apparatus in which the optical disk reproducing apparatus 11 displays an image based on information stored in the EDID memory 23 of the television receiver 12 and information stored in the EDID memory 35 of the AV amplifier 13. 3 is a flowchart summarizing operations for automatically determining the AV device that performs audio reproduction and controlling the display video and the reproduced audio to be synchronized.

  In the explanation of the operation here, an example is set in which the user performs viewing of the display image on the flat panel display 19 of the television receiver 12 and listening to the reproduced sound by the speaker 33 of the AV amplifier 13. Will be explained.

  That is, in this case, the user sets the television receiver 12 in an audio mute state, that is, a state in which the television receiver 12 is not used for listening to audio, and sets the AV amplifier 13 in a video mute state, that is, an AV amplifier. 13 is set so as not to be visually recognized.

  For this reason, in the EDID memory 23 of the television receiver 12, the time information AD1D indicating the time AD1 required for the audio signal processing in the audio processing unit 20 is set to “0”, and in the EDID memory 35 of the AV amplifier 13, The time information VD2D indicating the time VD2 required for the video signal processing in the video processing unit 30 is set to “0”.

  Here, when the processing is started (step S10), the control unit 51 of the optical disc playback apparatus 11 receives the AV apparatus (in this case, the receiving side) in both of the two input / output ports 49 and 50 in step S11. It is determined whether or not the television receiver 12 and the AV amplifier 13) are connected.

  If it is determined that it is connected (YES), the control unit 51 obtains the information requested from the television receiver 12 and stored in the EDID memory 23 in step S12, and in step S13, the AV device. 13 to obtain the information stored in the EDID memory 35.

  Thereafter, in step S14, the control unit 51 includes time information VD1D indicating the time VD1 required for the video signal processing in the video processing unit 18 among the information acquired from the EDID memories 23 and 35, and the audio in the audio processing unit 20. Time information AD1D indicating time AD1 required for signal processing, time information VD2D indicating time VD2 required for video signal processing in the video processing unit 30, and time information AD2D indicating time AD2 required for audio signal processing in the audio processing unit 32 Identify each value.

  In this case, as described above, the time information AD1D and VD2D are “0”, and the time information VD1D and AD2D have a predetermined value. Thereby, the control unit 51 is set in a state in which the television receiver 12 is not used for listening to audio, and is set in a state in which the AV amplifier 13 is not used for viewing visual images, that is, the television receiver. 12 and the audio reproduction by the AV amplifier 13 can be determined to be set.

  Therefore, in step S15, the control unit 51 sets time information VD1D indicating the time VD1 required for the video signal processing in the video processing unit 18 and time information AD2D indicating the time AD2 required for the audio signal processing in the audio processing unit 32. Is supplied to the delay adjustment unit 43 so that the video displayed on the flat panel display 19 of the television receiver 12 and the audio reproduced on the speaker 33 of the AV amplifier 13 are synchronized. The digital audio signal output from the decoding unit 42 is delayed, and the process is terminated (step S16).

  In the delay adjusting unit 43, the audio signal output from the audio processing unit 32 is synchronized with the video signal output from the video processing unit 18, that is, the shorter time required for signal processing is adjusted to the longer one. The delay adjustment unit 43 subtracts the time information AD2D from the time information VD1D to delay the digital audio signal output from the audio decoding unit 42 by the time obtained by subtracting the time information AD2D from the time information VD1D. Is delayed.

  The digital video signal output from the video decoding unit 41 of the optical disc playback apparatus 11 is supplied to the television receiver 12 and the AV amplifier 13 via the HDMI transmission units 44 and 45. Since it is set in the mute state, it is used for video display on the flat panel display 19 of the television receiver 12.

  Each digital audio signal output from the audio decoding unit 42 and the delay adjustment unit 43 is selected by the switch 47 of the selection unit 46 and supplied to the television receiver 12 via the HDMI transmission unit 44. Since the television receiver 12 is set in the audio mute state, it is not used for audio reproduction there.

  On the other hand, each digital audio signal output from the audio decoding unit 42 and the delay adjustment unit 43 is selected by the switch 48 of the selection unit 46 and supplied to the AV amplifier 13 via the HDMI transmission unit 45, where audio reproduction is performed there. To be served.

  In this case, assuming that the switch 48 is switched to supply the digital audio signal output from the delay adjustment unit 43 to the HDMI transmission unit 45 as shown in FIG. A digital audio signal that has been subjected to the delay processing of the amount necessary for synchronizing with the video is supplied. For this reason, in the AV amplifier 13, if the supplied digital audio signal is directly processed and reproduced by the speaker 33, the audio can be synchronized with the video. The means for transmitting this is the adjustment delay data CDL transmitted to the AV amplifier 13 side, which in this case is “0”. The adjustment delay data CDL is calculated on the optical disc reproducing apparatus 11 side, the delay is adjusted, and the adjustment value CDL in the subsequent stage is calculated and sent.

  If the switch 48 is switched to supply the digital audio signal output from the audio decoding unit 42 to the HDMI transmission unit 45 in the opposite manner to FIG. The signal in which the adjustment delay data CDL is multiplexed without being applied is supplied as HDMI transmission.

  In this case, the HDMI receiving unit 28 of the AV amplifier 13 separates the digital video signal and the audio signal from the input digital data, and then converts the HDMI signal into the adjustment delay data CDL multiplexed therein. It functions to perform delay processing based on the output. Therefore, in the AV amplifier 13, the HDMI receiving unit 28 performs signal processing on the digital audio signal that has been subjected to the delay processing of an amount necessary for synchronizing with the display video, and reproduces the audio on the speaker 33, thereby generating audio. Can be synchronized with the video.

  The switches 47 and 48 of the selection unit 46 are switched based on the control of the control unit 51. For example, the control unit 51 can identify the performance of each AV device based on the EDID acquired from the external AV device on the receiving side, and can control switching of the switches 47 and 48 according to the identification result. .

  According to the optical disk reproducing apparatus 11 described above, the television receiver 12 is based on the time information VD1D, AD1D, VD2D, AD2D stored in the EDID memories 23 and 35 of the television receiver 12 and the AV amplifier 13 on the receiving side. 12 is set by the user so as not to be used for listening to audio, and the AV amplifier 13 is automatically set so as not to be used for visual recognition, and is displayed by the television receiver 12. Since the video to be played and the audio reproduced by the AV amplifier 13 are controlled to be synchronized, handling for the user can be made very convenient.

  In the optical disc playback apparatus 11 described above, the digital audio signal subjected to the decoding process is supplied to the AV amplifier 13 to be played back. For example, the compressed form before the decoding process is performed. Of course, the digital audio signal may be supplied to the AV amplifier 13, and the audio signal may be decoded by the AV amplifier 13.

  FIG. 7 shows another example of a signal transmission system compliant with the HDMI standard. That is, this signal transmission system includes an STB (set top box) 52 as an AV apparatus on the transmission side.

  The digital video signal and audio signal generated by the STB 52 are converted into digital data in a form compliant with the HDMI standard, and then the receiving side AV device is connected to the receiving side AV device via the optical disc playback device 11 as a relay device. The television receiver 12 and the AV amplifier 13 are provided for video display and audio reproduction.

  FIG. 8 shows the signal processing system of the STB 52. That is, the television broadcast signal received by the antenna 53 is supplied to the channel selection / decoding unit 55 via the input terminal 54. The channel selection / decoding unit 55 selects a signal of a predetermined channel from the input television broadcast signal, and generates a digital video signal and audio signal by performing a decoding process on the selected signal. is doing.

  The digital video signal and audio signal generated by the channel selection / decoding unit 55 are supplied to the HDMI transmission unit 56. The HDMI transmission unit 56 temporally multiplexes the input digital video signal and audio signal and converts the digital video signal and audio signal into digital data conforming to the HDMI standard, via the output terminal 57 and the TMDS signal transmission path 58. Are output to the optical disk playback device 11.

  The STB 52 controls all the operations including the reception operation described above by the control unit 59. The control unit 59 has a built-in CPU 59a, and controls each unit based on operation information from the operation unit 59b so that the operation content is reflected.

  In this case, the control unit 59 uses the memory unit 59c. The memory unit 59c mainly includes a ROM that stores a control program executed by the CPU 59a, a RAM that provides a work area for the CPU 59a, and a nonvolatile memory that stores various setting information, control information, and the like. .

  The control unit 59 is connected via an input terminal 60 to a DDC communication path 61 for transmitting information read from an EDID memory, which will be described later, provided in the optical disc playback apparatus 11.

  FIG. 9 shows a signal processing system of the optical disc reproducing apparatus 11 when used as a relay apparatus. 9, the same parts as those in FIG. 5 are denoted by the same reference numerals. That is, digital data in a form conforming to the HDMI standard supplied from the STB 52 via the TMDS signal transmission path 58 is supplied to the HDMI receiving unit 63 via the input terminal 62 a of the input / output port 62.

  The HDMI receiving unit 63 separates the input digital data into a digital video signal and an audio signal. The digital video signal and audio signal output from the HDMI receiving unit 63 are supplied to the selection unit 46.

  In this case, the selection unit 46 supplies the digital video signal and audio signal output from the HDMI reception unit 63 to the HDMI transmission units 44 and 45, and the video decoding unit 41 of the disk playback unit 39. The digital video signal to be output is supplied to the HDMI transmission units 44 and 45, respectively, and the digital audio signal output from the audio decoding unit 42 and the digital audio signal output from the delay adjustment unit 43 are The function is expanded so that the switching as described above with reference to FIG. 5 and the supply to the HDMI transmission units 44 and 45 can be selectively performed.

  Further, the optical disk playback device 11 has an EDID memory 64 built therein. As described above, when the television receiver 12 is set to the audio mute state and the AV amplifier 13 is set to the video mute state, the control unit 51 acquires from the EDID memory 23 of the television receiver 12. The information related to the displayed video is copied, and the time information VD1D indicating the time VD1 required for the video signal processing in the video processing unit 18 includes information indicating the delay time VD3 of the video signal of the selection unit 46 in the optical disc playback apparatus 11. The added time information VD3D is recorded in the EDID memory 64.

  Further, the control unit 51 transcribes the information related to the audio display acquired from the EDID memory 35 of the AV amplifier 13, and also adds the time information AD2D indicating the time AD2 required for the audio signal processing in the audio processing unit 32 to the optical disc reproducing apparatus. 11, the time information AD3D obtained by adding the information indicating the delay time AD3 of the audio signal of the selection unit 46 is recorded in the EDID memory 64.

  Then, the time information VD3D and AD3D stored in the EDID memory 64 is read from the EDID memory 64 in response to a request from the STB 52 which is an AV apparatus on the transmission side, via the DDC communication path 61 of the input / output port 62. , Transmitted to the STB 52.

  Then, the control unit 59 of the STB 52 adds the time information VD3D acquired from the EDID memory 64 of the optical disc playback apparatus 11 and the video processing delay time in the channel selection / decoding unit 55 of the STB 52, and the time information AD3D and TB52. The difference between the sum and the audio processing delay time in the channel selection / decoding unit 55 is calculated, and information indicating the time corresponding to the difference is output to the HDMI transmission unit 56 as adjusted delay data CDL. As a result, the HDMI transmission unit 56 multiplexes the adjustment delay data CDL into a digital signal and outputs it.

  For this reason, the HDMI receiving unit 63 of the optical disc playback apparatus 11 separates the digital video signal and the audio signal from the input digital data, and then adjusts the digital audio signal multiplexed there. It functions to perform delay processing based on the data CDL and to output to the AV amplifier 13. For this reason, the AV amplifier 13 synchronizes the audio with the video by processing the digital audio signal that has already been subjected to the delay processing of the amount necessary for synchronizing with the display video and reproducing the sound with the speaker 33. It becomes possible.

  Even when the optical disk playback device 11 is used as a relay device as described above, the television receiver 12 is set by the user so as not to listen to audio, and the AV amplifier 13 is not used to view video. What is set by the user can be automatically identified.

  Then, with respect to the digital data output from the STB 52 that is the AV apparatus on the transmission side, the video displayed by the television receiver 12 and AV It can be controlled so that the sound reproduced by the amplifier 13 is synchronized, and handling for the user can be made very convenient.

  In the above description in which the optical disk playback device 11 is used as a relay device, the HDMI receiving unit 63 of the optical disk playback device 11 performs a delay process on the digital audio signal based on the adjustment delay data CDL included therein. However, the present invention is not limited to this, and the digital audio signal multiplexed with the adjustment delay data CDL is directly relayed to the AV amplifier 13, and the HDMI receiver 28 of the AV amplifier 13 receives the digital audio signal. The delay processing based on the adjustment delay data CDL included in the data may be performed.

  The STB 52 has a delay circuit for delaying the digital audio signal subjected to the decoding process, and the time information VD3D acquired from the EDID memory 64 of the optical disc playback apparatus 11 and the video in the channel selection / decoding unit 55 of the STB 52 The digital audio signal is delayed and output from the STB 52 by a time corresponding to the sum of the processing delay time and the difference between the time information AD3D and the sum of the audio processing delay time in the channel selection / decoding unit 55 of the STB 52. It is also possible to make it.

  Note that the present invention is not limited to the above-described embodiments as they are, and can be embodied by variously modifying the constituent elements without departing from the scope of the invention in the implementation stage. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above-described embodiments. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements according to different embodiments may be appropriately combined. In the above-described embodiment, HDMI is used. However, it is possible to use another interface standard that can transmit the state of the reception side to the transmission side, for example, IEEE1394.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram illustrating an example of a signal transmission system compliant with an HDMI standard, showing an embodiment of the present invention. The block block diagram shown in order to demonstrate the signal processing system of the television receiver used as the AV apparatus of the receiving side in the embodiment. 4 is a flowchart shown for explaining main processing operations of the television receiver in the embodiment. The block block diagram shown in order to demonstrate the signal processing system of AV amplifier used as the receiving side AV apparatus in the embodiment. The block block diagram shown in order to demonstrate the signal processing system of the optical disk reproducing | regenerating apparatus used as the transmission side AV apparatus in the embodiment. The flowchart shown in order to demonstrate main processing operation | movement of the optical disk reproducing | regenerating apparatus in the embodiment. The block block diagram shown in order to demonstrate the other example of the signal transmission system based on the HDMI specification in the embodiment. The block block diagram shown in order to demonstrate the signal processing system of STB used as the transmission side AV apparatus in the other example of the same signal transmission system. The block block diagram shown in order to demonstrate the signal processing system of the optical disk reproducing | regenerating apparatus used as the transmission side AV apparatus in the other example of the same signal transmission system.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11 ... Optical disk reproducing device, 12 ... Television receiver, 13 ... AV amplifier, 14 ... TMDS signal transmission path, 15 ... Input terminal, 16 ... HDMI receiving part, 17 ... Reproducing part, 18 ... Video processing part, 19 ... Flat Panel display, 20 ... Audio processing unit, 21 ... Speaker, 22 ... Control unit, 23 ... EDID memory, 24 ... Output terminal, 25 ... DDC communication path, 26 ... TMDS signal transmission path, 27 ... Input terminal, 28 ... HDMI reception , 29 ... playback unit, 30 ... video processing unit, 31 ... display, 32 ... audio processing unit, 33 ... speaker, 34 ... control unit, 35 ... EDID memory, 36 ... output terminal, 37 ... DDC communication path, 38 ... Optical disk, 39... Disk playback section, 40... Disk drive section, 41... Video decoding section, 42... Audio decoding section, 43 ... delay adjustment section, 44, 45. Transmission unit 46 ... Selection unit 47,48 ... Switch 49,50 ... I / O port 51 ... Control unit 52 ... STB 53 ... Antenna 54 ... Input terminal 55 ... Channel selection / decoding unit 56 ... HDMI transmission section 57... Output terminal 58. TMDS signal transmission path 59... Control section 60 .. input terminal 61... DDC communication path 62 62 I / O port 63 63 HDMI reception section 64.

Claims (13)

Receiving means for receiving a digital video signal and a digital audio signal;
Storage means for storing information indicating that when the sound is set to the mute state;
An AV apparatus comprising: control means for outputting information stored in the storage means to the outside.   At least a function of performing predetermined signal processing on the digital video signal received by the receiving means and displaying a video; and a function of performing predetermined signal processing on the digital audio signal received by the receiving means and reproducing sound. 2. The AV apparatus according to claim 1, further comprising a processing unit having one of them. The storage means stores the time required for signal processing by the processing means,
When the sound is set in the mute state, information indicating that is stored in the storage means by rewriting the information indicating the time required for signal processing by the processing means to a value that cannot be normally obtained. The AV apparatus according to claim 2, wherein: The storage means stores the time required for signal processing by the processing means,
When the sound is set to the mute state, the information indicating that is stored as the information indicating the time required for signal processing by the processing means by rewriting the value indicating that the time is “0”. 3. The AV apparatus according to claim 2, wherein the AV apparatus is stored in the means.   2. The AV apparatus according to claim 1, wherein the receiving unit receives the digital video signal and the digital audio signal as digital data in a form compliant with the HDMI standard.   The AV apparatus according to claim 1, wherein the storage means is an EDID memory. Transmitting means for transmitting digital video signals and digital audio signals to a plurality of electronic devices;
Obtaining means for obtaining information indicating that sound is set in a mute state from the plurality of electronic devices;
Based on the information acquired by the acquisition means, a setting state for audio mute of each of the plurality of electronic devices is determined, and the determination is made on at least one of the digital video signal and the digital audio signal transmitted by the transmission means. An AV apparatus comprising: control means for performing predetermined signal processing corresponding to the result.   8. The AV apparatus according to claim 7, wherein the control unit determines an electronic device that performs audio reproduction among the plurality of electronic devices based on the information acquired by the acquisition unit.   8. The AV apparatus according to claim 7, wherein the acquisition unit acquires a setting state for audio mute from the plurality of electronic devices as EDID. First means for storing information indicating that to the first AV device in which the sound is set to the mute state among the plurality of first AV devices;
A second AV device that transmits digital video signals and digital audio signals to the plurality of first AV devices for video display or audio playback is stored in the first AV device by the first means. A second means for acquiring the recorded information;
Based on the information acquired by the second means, a setting state for audio mute of each of the plurality of first AV devices is determined, and a digital video signal and digital audio transmitted from the second AV device are determined. 3. An interface system comprising: third means for performing predetermined signal processing corresponding to the determination result on at least one of the signals.   The third means determines a first AV apparatus capable of reproducing sound among the plurality of first AV apparatuses based on information acquired by the second means. 10. Interface method according to 10. First means for storing information indicating that to the first AV device in which the sound is set to the mute state among the plurality of first AV devices;
A second AV device that transmits digital video signals and digital audio signals to the plurality of first AV devices for video display or audio playback is stored in the first AV device by the first means. A second means for acquiring the recorded information;
Based on the information acquired by the second means, a setting state for audio mute of each of the plurality of first AV devices is determined, and a digital video signal and a digital audio signal are transmitted to the second AV device. And a third means for performing predetermined information processing corresponding to the determination result with respect to information acquired by the third AV device.   The third means selects EDID information acquired by the third AV device by selecting information on the video or audio operating state of the plurality of first AV devices. Item 12. The interface method according to item 12.

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