JP2013135454A - Electronic apparatus, and mutual video and voice output method of electronic apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic apparatus, and a mutual video and voice output method of an electronic apparatus.SOLUTION: The electronic apparatus includes a decoder, a video processing unit, a voice processing unit, a communication unit, and a control unit. The decoder decodes a content including at least one of video data and voice data. The video processing unit processes the video data decoded by the decoder to produce a video signal being displayed in a video display unit. The voice processing unit processes voice data decoded by the decoder to produce a voice signal being reproduced by a voice reproduction unit. The communication unit transmits the video data and voice data decoded by the decoder, the video signal processed by the video processing unit, and the voice signal processed by the voice processing unit to a destination apparatus. The control unit sets a combination of video data, voice data, video signal and voice signal being transmitted from the communication unit, for at least one of the function or characteristics of the destination apparatus.

Description

  Embodiments described herein relate generally to an electronic device connected by a bidirectional communication interface and a method for outputting video and audio between the electronic devices.

  In an electronic device connected by a bi-directional communication interface, for example, HDMI (High-definition Digital Media Interface) version 1.2a or later, video and audio playback capability and basic of the connection partner are connected between the devices of the connection partner. It is possible to exchange information.

JP 2009-89209 A

  An electronic device connected via a bi-directional communication interface such as HDMI (High-definition Digital Media Interface) is a source device that outputs content mainly composed of video and audio, and a sink that mainly processes and displays received content. (Sink) Roughly divided into equipment.

  In version 1.4 and later, baseband transmission and Ethernet transmission using Ethernet (registered trademark) are possible. In particular, in Ethernet transmission, compressed transmission according to the DLNA (Digital Living Network Alliance) standard is also possible.

  On the other hand, a source device, a sink device, and a cable (HDMI cable) that can be used for HDMI transmission have various characteristics according to the manufacturing time and generation of basic design. For this reason, there may be tradeoffs such as when the processing capability of the decoder of the source device is higher than the processing capability of the decoder of the sink device, or when the processing capability of the decoder is high but the power consumption is high.

  An object of the present invention is to provide an electronic device connected by a bidirectional communication interface and a video and audio output method between the electronic devices.

  According to the embodiment, the electronic device includes a decoder unit, a video processing unit, an audio processing unit, a communication unit, and a control unit. The decoder unit decodes content including at least one of video data and audio data. The video processing unit processes the video data decoded by the decoder unit into a video signal displayed by the video display unit. The audio processing unit processes the audio data decoded by the decoder unit into an audio signal reproduced by the audio reproduction unit. The communication unit transmits the video data and audio data decoded by the decoder unit, the video signal processed by the video processing unit, and the audio signal processed by the audio processing unit to a connection partner device. The control unit sets a combination of the video data, the audio data, the video signal, and the audio signal transmitted by the communication unit for at least one of the functions or characteristics of the connection partner device.

An example of the 1st electronic device (recording / reproducing apparatus) to which embodiment is applied and the 2nd electronic device (video display apparatus) connected to the 1st electronic device is shown. An example of a bidirectional interface (HDMI cable) for connecting a first electronic device (recording / playback device) to which the embodiment is applied and a second electronic device (video display device) connected to the first electronic device is shown. An example of a video and audio output method between a source device (first electronic device) and a sink device (second electronic device) connected to each other by a bidirectional communication interface to which the embodiment is applied will be described. An example of a video and audio output method between a source device (first electronic device) and a sink device (second electronic device) connected to each other by a bidirectional communication interface to which the embodiment is applied will be described. An example of a video and audio output method between a source device (first electronic device) and a sink device (second electronic device) connected to each other by a bidirectional communication interface to which the embodiment is applied will be described. An example of the “user selection screen” display in the video and audio output method between the source device and the sink device to which the embodiment is applied is shown. An example of the “user selection screen” display in the video and audio output method between the source device and the sink device to which the embodiment is applied is shown. 1 shows an example of a configuration of an electronic device (recorder device) that can be used as a source device to which the embodiment is applied. 2 shows an example of the configuration of an electronic device (television receiver) that can be used as a sink device to which the embodiment is applied.

  Hereinafter, embodiments will be described with reference to the drawings.

  FIG. 1A illustrates an example of a first electronic device (recording / playback device) to which the embodiment is applied and a second electronic device (video display device) connected to the first electronic device. In the embodiment, a recording / playback apparatus that records and reproduces content (video and audio or still images) as the first electronic device, for example, a recorder device, and the content (video and video) is mainly used as the second electronic device. A video display device that receives and displays audio or still images will be described as an example, but the present invention is not limited to this. That is, any device provided with a broadcast receiving device such as a broadcast receiving device, a mobile phone with a broadcast receiving function, a personal computer with a broadcast receiving function, and a video recording device equipped with the broadcast receiving device may be used. The broadcast is not limited to receiving radio waves propagating in the air, but may be broadcast capable of receiving a program distributed from a broadcasting station via a network such as a cable or an IP (Internet Protocol) network. The content is also referred to as a program, a stream, or a file, and may be only audio or music. In addition to moving images and still images, the video includes text broadcasting and data broadcasting display mainly composed of text.

  In FIG. 1A, a first electronic device (hereinafter also referred to as a source device) 101 includes a CPU (control block) 111 that is a main control unit, and a recording unit (storage) 112 that records (holds) content. Both the decoder 113 for decoding the content, the video processing unit 114 for processing the decoded video, the audio processing unit 115 for processing the decoded audio (Audio), and the connected counterpart device The communication interface 301 includes at least a signal transmission unit (communication unit) 116 that outputs content (compressed data itself), a decoded video signal, or a decoded audio signal. Note that the signal transmission unit (communication unit) 116 may be referred to as a transmission unit (Tx) from the position of the transmission side by regarding the sink device described below as the reception side.

  The control block (CPU) 111 controls, for example, the operation of each unit of the source device 101, power on / off, acceptance of user input, decoding by a decoder, signal transmission by the signal transmission unit 116, and the like.

  The recording unit (storage) 112 is a semiconductor memory represented by an HDD (Hard Disk Drive), an optical disk represented by Blu-ray (BD) standard, DVD standard, CD standard, etc., an SD (Secure Digital) memory card, etc. Can play back at least one arbitrary recording medium such as, etc., and can hold content according to a user request.

  The decoder 113 separates the content held by the recording unit 112, that is, various files converted into digital signals, into video signals (files) and audio signals (files), and then decodes them. As a file that can be decoded (played back), for example, audio / video (Video) content, or various data such as text data such as text and photo data, such as video (Video, video), for example, MPEG (Moving Picture Experts Group) -1, -2, -4 (H.264 / AVC), audio (Audio, voice / music), for example, MP3 (MPEG Audio layer-3), AC3 (Audio Code number 3) As for linear PCM (Pulse Coded Module) and still images, for example, JPEG (Joint Photographic Experts Group) is widely known. Note that a separation unit (Demux) may be provided in the preceding stage of the decoder 113, and the separation process (step) by the decoder 113 may be executed independently.

  When a monitor device (display) is connected to the source device 101, the video processing unit 114 outputs a video signal that can be displayed by the monitor device.

  When an audio playback device such as a speaker (or audio amplifier device) is connected to the source device 101, the audio processing unit 115 outputs an audio signal that can be played back by the device.

  Note that the decoder 113 can also leave the decoding process to the counterpart device based on the signal processing capability (function) and power consumption of the decoder held by the counterpart device connected through the bidirectional communication interface described below. Similarly, in the video processing unit 114, video processing can also be entrusted to the counterpart device based on the processing capability (reproduction function) and power consumption of the video processing unit of the counterpart device connected through the bidirectional communication interface. In addition, the voice processing unit 115 can also leave the voice processing to the partner device based on the processing capability (reproduction function) and power consumption of the partner device connected through the bidirectional communication interface.

  In this case, the comparison of the signal processing capabilities (functions) of the decoder 113, the video processing unit 114, and the audio processing unit 115 with the corresponding processing capabilities (functions) of the counterpart device is, for example, EDID (Extended Display Identification) of the counterpart device. Data (detected when HPD (Hot Plug Detected) is used to recognize the counterpart device through the bi-directional communication interface) and a CEC (Consumer Electronics Control) line described later, for example, a vendor command The processing capability (function) acquired by the above or the like can be realized in the CPU 111 or its firmware or an application (program) for detection.

  In FIG. 1A, a second electronic device 201 (hereinafter sometimes referred to as a sink device) 201 includes a CPU (control block) 211 that is a main control unit, and a recording unit (storage) 212 that records (holds) content. Among the decoder 213 for decoding the content, the video processing unit 214 for processing the decoded video, the audio processing unit 215 for processing the decoded audio (Audio), and the connected counterpart device, It includes at least a signal transmission unit (communication unit) 216 that receives content (compressed data itself) or a video signal decoded by a counterpart device or a decoded audio signal via a bidirectional communication interface. Note that the signal transmission unit (communication unit) 216 may be referred to as a reception unit (Rx) from the position of the reception side by regarding the above-described source device as the transmission side.

  The second electronic device 201 includes a monitor unit (display) 217 that displays reproduced video and a speaker 218 that outputs reproduced audio (audio).

  The control block (CPU) 211 controls, for example, the operation of each unit of the sink device 101, power on / off, user input reception, decoding by the decoder, signal transmission by the signal transmission unit 216, and the like.

  The recording unit (storage) 212 is an arbitrary recording medium such as an HDD, an optical disk represented by Blu-ray (BD) standard, DVD standard, CD standard, etc., a semiconductor memory represented by SD (memory) card, etc. At least one can be reproduced, and the content can be held according to a user request.

  The decoder 213 converts the contents held by the recording unit 212, that is, various files converted into digital signals, or files (contents) supplied from the source device 101 through the bidirectional communication interface into video signals (files) and audio signals (files). ) And then decode. As a file that can be decoded (reproduced), for example, audio / video content, or various data such as text data such as characters and photo data, such as video (moving image), for example, MPEG-1, -2, -4 For (H.264 / AVC), audio (speech / music), for example, MP3, AC3, linear PCM, and for still images, for example, JPEG are widely known. Note that a separation unit (Demux) may be provided in the previous stage of the decoder 213, and the separation process (step) by the decoder 213 may be executed independently.

  The video processing unit 214 executes predetermined processing so that the monitor unit (display) 217 can display the video signal (Video) decoded by the decoder 213 or supplied by the source device 101, and the monitoring unit To 217.

  The audio processing unit 215 outputs the audio signal (Audio) decoded by the decoder 213 or supplied after being decoded by the source device 101 to the speaker 218 so that the speaker 218 can reproduce it. Note that an audio reproduction device such as an audio amplifier device may be connected instead of or independently of the speaker 218.

  The decoder 213 can also leave the decoding process to the counterpart device based on the signal processing capability (function) and power consumption of the decoder held by the counterpart device connected through the bidirectional communication interface described below. Similarly, in the video processing unit 214, video processing can be entrusted to the counterpart device based on the processing capability (reproduction function) and power consumption of the video processing unit of the counterpart device connected through the bidirectional communication interface. The voice processing unit 215 can also leave the voice processing to the counterpart device based on the processing capability (reproduction function) and power consumption of the counterpart device connected through the bidirectional communication interface.

  In this case, the comparison of the signal processing capabilities (functions) of the decoder 213, the video processing unit 214, and the audio processing unit 215 with the corresponding processing capabilities (functions) of the counterpart device is based on, for example, EDID extracted by the counterpart device. When the counterpart device recognizes (own device) and acquires information on the function of the own device through a vendor command or the like using the CEC line described later, the counterpart device (here, the CPU 111 of the source device 101 or its This can be realized in firmware or an application (program) for detection.

  In FIG. 1A, a bidirectional communication interface (for example, conforming to the High-definition Digital Media Interface (HDMI) standard) 301 includes a transmission unit (communication unit) 116 of the source device 101 and a reception unit (communication unit) 216 of the sink device 201. A connector 311 to be connected is provided. The two connectors 311 are connected by a transmission line (cable) 310 having a predetermined length. The connector 311 has no identification of transmission and reception, which is the transmission side and the other one is the reception side.

  The transmission path 310, which will be described in detail later with reference to FIG. 1B, includes a first transmission path (baseband transmission path) 321 that performs baseband transmission (HDMI transmission) and a second transmission path that performs compression transmission (Ethernet transmission). A transmission line (Ethernet transmission line) 331 and a CEC (Consumer Electronics Control) line 341 are included.

  In the transmission line 310 shown in FIG. 1B, a first transmission line (baseband transmission line) 321 is a video signal, for example, (R (red (red)) in TMDS (Transition-Minimized Differential Signaling). ), G (green), B (blue)) or YCbCr, data used for transmission of audio data (Data0, Data1, Data2), and baseband transmission (HDMI transmission) that transmits a signal using a CK line used for transmission of clock CK )I do. The second transmission path (Ethernet transmission path) 331 performs the above-described compressed transmission (Ethernet transmission). As described above, a CEC (Consumer Electronics Control) line 341 can exchange information (inter-device control signal) regarding each function between the sink device 201 and the source device 101 through a vendor command or the like.

  Further, the baseband transmission path 321 may be, for example, a dual link capable of transmitting a video signal having a higher resolution than TMDS.

  On the other hand, the Ethernet transmission path 331 uses the HDMI 301 HPD line and RSV (Reserve) line to decode in the communication unit 116 on the source device 101 side (also referred to as HDMI-HEC (HDMI Ethernet Channel)). The content in a compressed state not accompanied by the message is supplied to the communication unit 216 on the sink device 201 side as it is. Note that Ethernet transmission using the HPD line and the RSV line may be referred to as HDMI-HEC (Ethernet Channel).

  FIG. 2 shows a recording / playback device (source device / first electronic device) and a video display device (sink device / second electronic device) connected to each other by the bidirectional communication interface shown in FIGS. 1A and 1B. 2 shows an example of a video and audio output method.

  The first and second electronic devices, i.e., the source device and the sink device, have various characteristics (differences) according to the manufacturing time, the basic design generation (element component specifications), and the like. For this reason, when the processing capability of the decoder of the source device is high compared to the processing capability of the decoder of the sink device, or when the processing capability of the decoder is high but the power consumption is large, etc. There may be tradeoffs associated with some combinations that the user can select.

  That is, when the source device 101 and the sink device 201 are connected via the bidirectional communication interface (HDMI) 301, elements (configurations) of the source device 101 and the sink device 201, for example, a decoder, a video processing unit, and an audio processing unit For example, a combination that minimizes power consumption, prioritizes sound quality, or prioritizes image quality can be set (selected) automatically (or by user settings). Note that in the example described below, as a component with a trade-off, a decoder (113 on the source device side, 213 on the sink device side), a video processing unit (114 on the source device side, 214 on the sink device side), and audio processing The units (115 on the source device side, 215 on the sink device side) will be described as a representative. Therefore, it is possible to add judgments regarding more elements. Further, it goes without saying that the above-described elements may be combined into one or separated into a plurality of four or more elements due to changes in the manufacturing form of the elements.

  For example, when the initial setting of each of the source device 101 and the sink device 201 is a power saving (minimum power consumption) setting, a source connected by the HDMI 301 as described below with reference to FIG. By comparing the power consumption of each of the device 101 and the sink device 201, a device with less power consumption can be selected (automatically).

  That is, the power consumption of the decoder 113 of the source device 101 (see FIG. 1A) is P1, the power consumption of the video processing unit 114 is P2, the power consumption of the audio processing unit 115 is P3, and the decoder of the sink device 201 (see FIG. 1A). If the power consumption of 213 is P4, the power consumption of the video processing unit 214 is P5, and the power consumption of the audio processing unit 215 is P6, P101 (source device) that is “P1 + P2 + P3” is obtained [21], “P4 + P5 + P6”. P201 (sink device) is obtained [22], P101 and P201 are compared [23], and “P101 <P201”, that is, when the power consumption of the source device 101 is less than the power consumption of the sink device 201 [23-YES ] The video and audio decoded by the decoder 113 of the source device 101 are respectively converted into the video processing unit 114 ( Processing is performed in the source device 101 side) and the audio processing unit 115 (source device 101 side), and is supplied to the sink device 201 via the HDMI 301 (baseband (first) transmission path 321 using TMDS shown in FIG. 1B). Good [24].

  On the other hand, when “P101 <P201” is different (P101 ≧ P201) [23-NO], the content (file) held by the recording unit 112 of the source device 101 is transferred via the Ethernet (second) transmission path 331. The video and audio supplied to the sink device 201 and decoded by the decoder 213 of the sink device 201 may be reproduced by the video processing unit 214 and the audio processing unit 215, respectively [25].

  FIGS. 3A and 3B illustrate the case where a source device and a sink device connected to each other using the bidirectional communication interface (HDMI) 301 have a trade-off associated with an arbitrary combination that can be selected by the user, at an arbitrary timing. An example in which the user can set (select) is shown.

For example, in each of the source device 101 and the sink device 201,
The power consumption of the decoder 113 on the source device 101 side is P1, the function of the video processing unit 114 is F1 (power consumption is P2), the deviation of the main clock MC of the audio processing unit 115 is A (power consumption is P3),
The power consumption of the decoder 213 on the sink device 201 side may be P4, and the function of the video processing unit 214 may be different from F2, that is, the function (F1) of the decoder 113 on the source device 101 side (power consumption is P5). The deviation of the main clock MC may differ from B, that is, the deviation (A) of the decoder 113 on the source device 101 side (power consumption is P6).
Suppose that

  Note that the function F1 of the video processing unit 114 of the source device 101 and the function F2 of the video processing unit 214 of the sink device 201 include, for example, a 3DDNR type in which noise reduction (DNR) is performed in association with images of a plurality of frames. Differences in superiority such as the 2DDNR type that processes only the image of the frame.

  The deviation of the main clock MC is, for example, the stability of a 48 MHz clock used for reproduction of CS (Communication Satellite, relayed using a communication satellite) broadcast (how accurate the clock is with respect to 48 MHz). There is a clear difference (about 10% difference).

  Hereinafter, on the source device 101 side, video data and audio data obtained by decoding the content (file) held by the recording unit 112 of the source device 101 are reproduced by the video processing unit 114 and the audio processing unit 115 on the source device 101 side. The “baseband (HDMI) transmission” for supplying the video and audio signals to the sink device 201 via HDMI 301 is “Transmission A”, and the content (file) held by the recording unit 112 of the source device 101 is directly used by the HDMI 301 as it is. The “Ethernet transmission” in which the video data and the audio data that are supplied to and decoded by the decoder 213 of the sink device 201 in the video processing unit 214 and the audio processing unit 215 are called “transmission B”.

  Because of the trade-off described below, “Transmission C” for transmitting baseband (HDMI) for video and Ethernet for transmitting audio, and baseband transmitting for audio and video for Ethernet There is “Transmission D” to be transmitted.

  First, it is detected that the source device 101 and the sink device 201 are connected via the HDMI 301 [101], and that there is a trade-off between “power consumption” and “image quality (video) / sound quality (sound)”. Check [102].

  When there is no trade-off [102-NO], it is checked that the function of the source device 101 is higher than the function of the sink device 201 (the source device 101 is superior to the sink device 201) [111].

  When the function of the source device 101 is higher than the function of the sink device 201 (the source device 101 is superior to the sink device 201) [111-YES], “Transmission A” is adopted (set) for video / audio transmission. [112]. Accordingly, when the function of the sink device 201 is higher than the function of the source device 101 [111-NO], “Transmission B” is adopted (set) for video / audio transmission [113].

  When there is a trade-off [102-YES], a “user selection screen” display 401 shown as an example in the latter part of FIG. 4 is displayed on the monitor unit 217 of the sink device 201, and the user “combines devices with less power consumption”. Can be selected, for example, “power priority” display 411 and “image quality (video quality) and sound quality (audio quality)” can be selected, for example, “image quality / sound quality priority” display 412 Prompts the input of a control input [103].

  When “power priority” to apply a combination with low power consumption is instructed (by the user) [104-YES], the source device 101 has less power consumption than the sink device 201 (the source device 101 is the sink device). [121].

  When the power consumption of the source device 101 is less than the power consumption of the sink device 201 [121-YES], “Transmission A” is adopted (set) for video / audio transmission [122]. Accordingly, when the power consumption of the source device 101 is higher than the power consumption of the sink device 201 [121-NO], “Transmission B” is adopted (set) for video / audio transmission [123].

  When “image quality / sound quality priority” giving priority to image quality / sound quality is instructed (by the user) from the “user selection screen” display 401 shown as an example in the subsequent stage in FIG. 4 [104-NO], between image quality and sound quality It is checked that there is a tradeoff [105].

  If it can be checked that there is no trade-off [105-NO], it is checked that the function of the source device 101 is higher than the function of the sink device 201 (the source device 101 is superior to the sink device 201). [161].

  When the function of the source device 101 is higher than the function of the sink device 201 (the source device 101 is superior to the sink device 201) [161-YES], “Transmission A” is adopted (set) for video / audio transmission. [162]. Accordingly, when the function of the sink device 201 is higher than that of the source device 101 [161-NO], “Transmission B” is adopted (set) for video / audio transmission [163].

  On the other hand, if there is a trade-off [105-YES], it is checked that image quality and sound quality can be set separately [106].

  When the image quality and the sound quality can be set separately [106-YES], which of the image processing functions of the source device 101 and the sink device 201 is higher, that is, the function of the source device 101 is higher than the function of the sink device 201. Checked [131].

  When the (video processing) function of the source device 101 is higher than the (video processing) function of the sink device 201 [131-YES], the video data is subjected to video processing in the source device 101 and then transmitted to the baseband as a video signal, and audio data "Transmission C" is adopted (set) as Ethernet transmission in which audio data is transmitted as is to the sink device 201 (audio processing is performed by the sink device 201) [132].

  On the other hand, when the (video processing) function of the sink device 201 is higher than the (video processing) function of the source device 101 [131-NO], the video data is directly transmitted to the sink device 201 (video processing is performed by the sink device 201). Using “Ethernet transmission”, “transmission D” is performed (set), in which audio data is subjected to audio processing in the source device 101 and transmitted as baseband as an audio signal [133].

  When the image quality and the sound quality cannot be set separately [106-NO], a “user selection screen” display 501 shown as an example in the latter part of FIG. 5 is displayed on the monitor unit 217 of the sink device 201, and the user receives the “image quality ( Input of control input corresponding to, for example, a “quality priority” display 511 and a “sound quality priority” display 512 that can be selected to give priority to “sound quality (sound)”, for example. [107].

  When “image quality priority” giving priority to image quality is instructed (by the user) from the “user selection screen” display 501 [108-YES], which of the image quality processing functions of the source device 101 and the sink device 201 is higher? That is, it is checked that the function of the source device 101 is higher than the function of the sink device 201 [141].

Hereinafter, when the video processing capability (function) of the source device 101 is higher than the video processing capability (function) of the sink device 201 [141-YES], “Transmission A” is adopted (set) for video / audio transmission. [142]. Accordingly, when the video processing capability (function) of the sink device 201 is higher than the video processing capability (function) of the source device 101 [141-NO], “Transmission B” is adopted (set) for video / audio transmission. [143].
On the other hand, for example, when “sound quality priority” giving priority to sound quality is instructed from the “user selection screen” display 501 (by the user) [108-NO], which of the processing capabilities of the source device 101 and the sink device 201 is concerned with the sound quality. It is checked whether (function) is high, that is, the function of the source device 101 is higher than the function of the sink device 201 [151].

  Hereinafter, when the audio processing capability (function) of the source device 101 is higher than the audio processing capability (function) of the sink device 201 [151-YES], “Transmission A” is adopted (set) for video / audio transmission. [152]. Accordingly, when the audio processing capability (function) of the sink device 201 is higher than the audio processing capability (function) of the source device 101 [151-NO], “Transmission B” is adopted (set) for video / audio transmission. [153].

  If “power priority” is input [104-YES], “P1 + P2 + P3” is P101 (power consumption of the source device) and “P4 + P5 + P6” according to the example already described with reference to FIG. P201 (sink device power consumption) is compared.

If the input instruction is “image quality / sound quality priority” [104-NO],
Function F1 of the video processing unit 114 of the source device 101,
Function F2 of the video processing unit 214 of the sink device 201,
Deviation A of the main clock MC of the audio processing unit 115 of the source device 101, and
Deviation B of the main clock MC of the audio processing unit 215 of the sink device 201,
Is extracted (prepared in a state where (difference) can be determined by the CPU 111 of the source device 101),
There is a difference between the function F1 of the video processing unit 114 of the source device 101 and the function F2 of the video processing unit 214 of the sink device 201 (difference in design generation (spec of component parts)), and Is there a difference between the deviation A of the main clock MC of the audio processing unit 115 and the deviation B of the main clock MC of the audio processing unit 215 of the sink device 201 (difference in design generation (spec of component parts))? In addition, the CPU 111 of the source device 101 checks whether there is a trade-off between sound quality and both.

  FIG. 6 shows an example of the configuration of an electronic device that can be used as a source device (recorder device) connected by the HDMI cable shown in FIG. 1A.

  A recorder (recording / reproducing device) 601 includes a tuner 602, an input circuit 603, a DSP (digital signal processor) 604, a recording device 605, an output circuit 606, a user operation input unit (remote control signal receiving circuit) 607, a power supply unit 608, and an HDMI. At least a port 681 connected to the processing unit 609 is included.

  The tuner 602 selects a channel for broadcasting a program to be recorded via an antenna or an optical cable connected to the antenna terminal 621.

  The input terminal 603 receives a video (moving image) signal and an audio (sound) signal input via the video (Viedo) input terminal 631 and the audio (Audio) input terminal 632.

  The DSP (signal processor) 604 includes a main controller (CPU) 640, a network controller 641, an analog-digital converter (ADC) 642, an encoder 643, an interface 644, a decoder 645, a user interface graphic processing unit (GUI processing unit) 646, It includes at least elements such as a signal processing unit 647, a selector 648, and an EPG (Electric Program Guide) processing unit 649.

  The DSP (signal processor) 604 performs predetermined image processing on the input image signal, and outputs it to the output circuit 606 and the HDMI interface unit 609 (via the interface 644).

  The main control unit (CPU) 640 controls the operation of each element described above, the on / off control of the main power supply (except for the secondary circuit for internal control) of the power supply unit 608, and the connection partner described with reference to FIGS. Detection and determination of power consumption and function (element generation) differences between devices are executed.

  The network controller 641 receives a stream format program supplied from an external network via the LAN terminal 691. The LAN terminal 691 is connected to, for example, a relatively small network (home LAN (Local Area Network)) or home server (Home Saver, large capacity recording device) and a connection network constructed in the same building, For example, it may be connected to an external network via a home server. The home LAN or network preferably conforms to the DLNA (Digital Living Network Alliance (registered trademark)) standard.

  An analog-to-digital converter (ADC) 642 converts an analog input video signal and audio signal into a digital signal and inputs the digital signal to the encoder 643. Needless to say, when the tuner 602 receives a digital broadcast, the output of the tuner 602 is directly input to the encoder 643.

  The encoder 643 converts (encodes) the input analog signal (video / audio) into a digital signal. For example, compression conforming to MPEG-2 or MPEG-4 (H.264-AVC)) is involved.

  The interface 644 is used to exchange data with the recording apparatus 5 or to input a control signal from the remote control signal light receiving circuit 607. For example, a television device (video reproduction device) 701 or a hub shown in FIG. 7 (FIG. 1A), for example, is connected to the HDMI processing unit 609 via an HDMI terminal 681. Note that an external device such as an AV amplifier having an HDMI terminal, a PC, a DVD recorder with a built-in HDD, or a DVD player can be connected to the hub. When the HDMI terminal 681 is connected to a hub, for example, via a broadband router, for example, connection to a network such as the Internet, a PC located on the network, a mobile phone or a mobile terminal device (not shown), or a mobile phone It is also possible to read and play and write (record) video files (video data) and audio files (audio data) with the terminal. The above-described HDMI processing unit 609 is connected to the interface 644, but the HDMI processing unit 609 may be connected to the network controller 641.

  The decoder 645 decodes a program compressed to MPEG-2 or MPEG-4 (H.264-AVC)) or the like.

  The user interface graphic processing unit (GUI processing unit) 646 outputs a GUI (graphic interface) screen display to be displayed on the monitor device 663 connected to the video output terminal 661 and the audio output terminal 662 via the output circuit 606.

  The EPG processing unit 649 acquires, for example, EPG data transmitted together with a program in BS digital broadcasting or terrestrial digital broadcasting, or EPG data that can be acquired from the outside via the LAN terminal 691. For example, the GUI processing unit 646 reserves a program. Sometimes it is stored as date, time, channel, program length data for displaying the program guide. The acquired EPG data is stored in a predetermined area of a memory device (not shown) or HDD 651 (recording unit 112 in FIG. 1A).

  The recording device 605 includes, for example, a disk drive device 652 (in FIG. 1A, integrated description as the recording unit 112) in addition to the HDD 651. The recording device 605 is an HD in the HDD 651 or a DVD standard optical disc D set in the disk drive device 652. On the other hand, a program is recorded, or an already recorded program is reproduced. In addition to the disk drive device 652, for example, a reader / writer (not shown) for recording a program in a semiconductor memory (memory card) or the like or reproducing an already recorded program may be prepared.

  The output circuit 606 outputs the video signal from the video encoder 647 and the audio signal from the DAC 648 to a playback device connected to the video output terminal 661 and the audio output terminal 662, for example, a monitor device and a speaker device.

  The remote control signal light receiving circuit 607 inputs the user operation input received by the remote control light receiving unit 671 to the CPU (main control device) 640 via the interface 644.

  The power supply unit 608 can turn off the main power supply under the control of the CPU 640, and turns on the main power supply when a reservation time set in a timer unit (not shown) has arrived, so that the operation of each element described above is made operable. maintain.

  FIG. 7 illustrates an example of a configuration of a television receiver (second electronic device) that can be used in the video display device (sink device) illustrated in FIG. 1A.

  The broadcast receiving apparatus 701 includes a broadcast input terminal 710, a tuner 711, a demodulator 712, a signal processor 713, a communication interface 714, an audio processor 721, a video processor 731, an OSD processor 732, a display processor 733, and a controller 750. , An operation input unit 761, a first light receiving unit 762, a card connector 764, a USB connector 766, a disk drive 770, and a power supply control unit 780. The broadcast receiving apparatus 701 further includes a speaker 218 and a display 217.

  The broadcast input terminal 710 is an input terminal to which a digital broadcast signal received by the antenna 219 is input, for example. The antenna 219 receives, for example, a terrestrial digital broadcast signal, a BS (Broadcasting Satellite) digital broadcast signal, and / or a 110-degree CS (Communication Satellite) digital broadcast signal. That is, content such as a program supplied by a broadcast signal is input to the broadcast input terminal 710.

  The broadcast input terminal 710 supplies the received digital broadcast signal to the tuner 711. The tuner 711 is a tuner for digital broadcast signals. The tuner 711 tunes (tunes) the digital broadcast signal supplied from the antenna 219. The tuner 711 transmits the tuned digital broadcast signal to the demodulation unit 712.

  The demodulator 712 demodulates the received digital broadcast signal. The demodulator 712 inputs the demodulated digital broadcast signal (content) to the signal processor 713. That is, the antenna 219, the tuner 711, and the demodulator 712 function as receiving means for receiving content.

  The signal processing unit 713 functions as a signal processing unit that performs signal processing on a digital broadcast signal (moving content data). The signal processing unit 713 performs signal processing on the digital broadcast signal supplied from the demodulation unit 712. That is, the signal processing unit 713 separates the digital broadcast signal into a video signal, an audio signal, and other data signals. The signal processing unit 713 supplies an audio signal to the audio processing unit 721. In addition, the signal processing unit 713 supplies a video signal to the video processing unit 731. Further, the signal processing unit 713 supplies a data signal to the control unit 750 and / or the OSD processing unit 732.

  The signal processing unit 713 performs signal processing on the digital signal received from the communication interface 714. For example, the signal processing unit 713 separates the digital signal into a digital video signal, a digital audio signal, and a data signal. The signal processing unit 713 supplies a digital audio signal to the audio processing unit 721. Further, the signal processing unit 713 supplies a digital video signal to the video processing unit 731. Further, the signal processing unit 713 supplies a data signal to the control unit 750 and / or the OSD processing unit 732.

  The signal processing unit 713 selects and processes either content input to the communication interface 714 or content input to the broadcast input terminal 710. That is, the signal processing unit 713 performs signal separation processing on either the digital broadcast signal or the digital signal.

  The audio processing unit 721 converts the digital audio signal received from the signal processing unit 713 into a signal (audio signal) in a format that can be reproduced by the speaker 218. The audio processing unit 721 supplies an audio signal to the speaker 218. The speaker 218 reproduces sound based on the supplied audio signal.

  The video processing unit 731 converts the video signal received from the signal processing unit 713 into a video signal having a format that can be reproduced by the display 219. That is, the video processing unit 731 decodes (reproduces) the video signal received from the signal processing unit 713 into a video signal having a format that can be reproduced by the display 219. In addition, the video processing unit 731 superimposes the OSD signal supplied from the OSD processing unit 132 on the video signal. The video processing unit 731 outputs the video signal to the display processing unit 733.

  The OSD processing unit 732 executes detection and determination of a difference in power consumption and function (element generation) between the signal processing unit 713 and the connection destination device described with reference to FIGS. A GUI (Graphical User Interface) screen, subtitles, time, or other information is superimposed on the screen based on a data signal that is heavily rained and / or a control signal supplied from the control unit 150. An OSD signal to be displayed is generated.

  The display processing unit 733 performs, for example, color, brightness, sharpness, contrast, or other image quality adjustment processing on the received video signal based on the control from the control unit 750. The display processing unit 733 supplies the video signal whose image quality has been adjusted to the display 217. The display 217 displays a video based on the supplied video signal.

  The display 217 includes, for example, a liquid crystal display device including a liquid crystal display panel including a plurality of pixels arranged in a matrix and a backlight that illuminates the liquid crystal panel. The display 217 displays video based on the video signal supplied from the broadcast receiving device 701.

  Note that the broadcast receiving device 701 may be configured to include a video output terminal instead of the display 217. The broadcast receiving apparatus 701 may be configured to include an audio output terminal instead of the speaker 218.

  The control unit 750 functions as a control unit (main control block) that controls the operation of each unit of the broadcast receiving device 701. The control unit 750 includes a CPU (main control unit) 751, a ROM (read only memory) 752, a RAM (rewritable (random access) memory) 153, an EEPROM (nonvolatile memory) 754, a clock (CLK) 755, and the like. I have. The control unit 750 performs various processes based on the operation signal supplied from the operation input unit 761.

  The CPU 751 includes arithmetic elements that execute various arithmetic processes, a memory area that holds and executes firmware, and the like. The CPU 751 realizes various functions by executing programs stored in the ROM 752 or the EEPROM 754. Further, the CPU 751 detects the difference in power consumption and function (element generation) described with reference to FIGS. 2 and 3 with respect to the connection partner device, that is, the source device (see FIG. 1A or FIG. 6) 101 (600). It is possible to read information stored in the EDID.

  The ROM 752 stores a program for controlling the broadcast receiving apparatus 701, a program for realizing various functions, and the like. The CPU 751 activates a program stored in the ROM 752 based on the operation signal supplied from the operation input unit 761. Thereby, the control unit 750 controls the operation of each unit.

  The RAM 753 functions as a work memory for the CPU 751. That is, the RAM 753 stores calculation results of the CPU 751, data read by the CPU 751, input information input by the operation input unit 761 or a remote controller (hereinafter referred to as a remote controller) 763, and the like.

  The EEPROM 754 stores various setting information and programs.

  The control unit 750 also includes a card_IF 755, a network connection unit (communication_IF) 756, and an HDMI 757 that can read information from the card-like medium (memory card) M, which is a semiconductor memory, and write information to the memory card M. (Corresponding to the signal transmission unit (communication unit) 116 in FIG. 1A) USB_I / F758, and i. An arbitrary number of I / F (Interface) groups such as Link_I / F (interface) 759 are connected to function as an external device, a hub (expansion device), or a network control device suitable for each interface.

  The card_IF (interface) 755 is an interface for communicating with, for example, a memory card M that stores moving image content. The card_IF 755 reads content data from the connected memory card M and supplies it to the control unit 750.

  For example, a recorder (video reproduction device / first electronic device) 201 shown in FIG. 6 or an AV amplifier or a hub (not shown) is connected to the HDMI 756 via an HDMI terminal 782. Although not shown, for example, a DVD recorder or a DVD player is connected to the AV amplifier. Further, for example, an AV amplifier having an HDMI terminal, an external device such as a PC, an HDD built-in DVD recorder, or a DVD player can be connected to the hub. When the HDMI terminal 782 is connected to a hub, for example, via a broadband router, for example, connected to a network such as the Internet, a PC located on the network, a mobile phone (not shown) or a mobile terminal device, or a mobile phone It is also possible to read and play and write (record) video files (video data) and audio files (audio data) with the terminal.

  A USB (Universal Serial Bus) _I / F (interface) 758 is an interface for communicating with the USB device 767. The USB_I / F 758 supplies a signal supplied from the connected USB device 767 to the control unit 750.

  For example, when the USB device 767 is an operation input device such as a keyboard, the USB_I / F 758 receives an operation signal from the USB device 767. The USB_I / F 758 supplies the received operation signal to the control unit 750. In this case, the control unit 750 executes various processes based on the operation signal supplied from the USB_I / F 758.

  For example, when the USB device 767 is a storage device that stores moving image content data, the USB_I / F 758 can acquire content from the USB device 767. The USB_I / F 758 supplies the acquired content to the control unit 750.

  The operation input unit 761 is an input unit including, for example, an operation key, a keyboard, a mouse, or another input device that can generate an operation signal in response to an operation input. For example, the operation input unit 761 generates an operation signal according to the operation input. The operation input unit 761 supplies the generated operation signal to the control unit 750. When the broadcast receiving device 701 includes the display 217, the operation input unit 761 may include a touch panel formed integrally with the display 217.

  The light receiving unit 762 includes, for example, a sensor that receives an operation signal from the remote controller 763. The first light receiving unit 762 supplies the received signal to the control unit 750. The control unit 750 receives the signal supplied from the first light receiving unit 762, amplifies the received signal, and performs A / D conversion, thereby decoding the original operation signal transmitted from the remote controller 763.

  The remote controller 763 generates an operation signal based on a user operation input. The remote control 763 transmits the generated operation signal to the light receiving unit 762 by infrared communication. Note that the light receiving unit 762 and the remote controller 763 may be configured to transmit and receive operation signals by other wireless communication such as radio waves.

  The disk drive 770 is equipped with, for example, a compact disk (CD), a digital versatile disk (DVD), a Blu-ray disk (Blu-ray Disk (registered trademark) / BD), or another optical disk M capable of recording moving image content data. Have a drive available. The disk drive 770 reads content from the optical disk M that is loaded, and supplies the read content to the control unit 750.

  The power control unit 780 controls power supply to each unit of the broadcast receiving device 701. The power supply control unit 780 receives power from the commercial power supply 500, for example. The commercial power supply 500 supplies AC power to the power supply control unit 780. The power supply control unit 780 converts the received AC power into DC and supplies it to each unit. Note that the power supply control unit 780 may directly receive direct current converted through an AC adapter, for example.

  Further, the broadcast receiving apparatus 701 may further include another interface. The interface is, for example, Serial-ATA (Serial-Advanced Technology Attachment), LAN (Local Area Network) port, or the like. The broadcast receiving device 701 can acquire and play back content recorded in a device connected by an interface. The broadcast receiving apparatus 701 can output the reproduced audio signal and video signal to a device connected by an interface.

  Further, when the broadcast receiving device 701 is connected to a network via an interface, the broadcast receiving device 701 can acquire and reproduce content data of a moving image on the network.

  Furthermore, the broadcast receiving apparatus 701 may include a storage device such as a hard disk drive (HDD, mass storage device) or an SSD (Solid State Drive, ie, a reader / writer capable of recording and reading data on a semiconductor memory device). good. When the storage device stores moving image content data, the broadcast receiving device 701 can read and reproduce the content stored in the storage device. Also, the broadcast receiving device 701 can store content supplied by, for example, a broadcast signal or a network in this storage device.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 101 ... Recorder apparatus (recording / reproducing apparatus / source device / first electronic device), 111 ... CPU (control block), 112 ... Recording unit, 113 ... Decoder, 114 ... Video processing unit, 115 ... Audio ) Processing unit 116 ... Signal transmission unit (communication unit) 201 ... Video display device (monitor device or display / sink device) 211 ... CPU (control block) 212 ... Recording unit 213 ... Decoder, 214 ... Video ( Video) processing unit, 215 ... Audio processing unit, 216 ... Signal transmission unit (communication unit), 217 ... Display (monitor unit), 218 ... Speaker, 219 ... Antenna, 301 ... HDMI (bidirectional communication interface), 310 ... Transmission path, 311 ... Connector, 321 ... Baseband (HDMI) transmission unit, 331 ... Compression (Ethernet) transmission unit, 341 CEC line 601 ... recording and reproducing apparatus (recorder / source device), 609 ... bi-directional communication interface (HDMI unit), 701 ... image display device (television receiver / sink device), 756 ... HDMI unit.

Claims (13)

A decoder unit for decoding content including at least one of video data and audio data;
A video processing unit that processes the video data decoded by the decoder unit into a video signal displayed by the video display unit;
An audio processing unit for processing the audio data decoded by the decoder unit into an audio signal reproduced by an audio reproduction unit;
A communication unit for transmitting the video data and the audio data decoded by the decoder unit, the video signal processed by the video processing unit and the audio signal processed by the audio processing unit to a connection partner device;
A controller configured to set a combination of the video data, the audio data, the video signal, and the audio signal transmitted by the communication unit with respect to at least one of functions or characteristics of the connection partner device;
An electronic device comprising:   The electronic device according to claim 1, wherein the control unit compares the function or characteristic of the connection partner device with its own function or characteristic and sets a combination that realizes a high function or a higher characteristic.   The electronic device according to claim 1, wherein the function or characteristic set by the control unit includes at least an item related to power consumption.   The electronic apparatus according to claim 1, wherein the function or characteristic set by the control unit includes at least an item related to the characteristic of the video processing unit.   The electronic device according to claim 1, wherein the function or characteristic set by the control unit includes at least an item related to the characteristic of the sound processing unit.   The electronic apparatus according to claim 2, further comprising a control input unit that enables an external setting regarding the function or characteristic set by the control unit.   The electronic device according to claim 3, further comprising a control input unit that enables an external setting regarding a function or characteristic set by the control unit. A decoder unit for decoding content including at least one of video data and audio data;
A video processing unit that processes the video data decoded by the decoder unit into a video signal displayed by the video display unit;
An audio processing unit for processing the audio data decoded by the decoder unit into an audio signal reproduced by an audio reproduction unit;
A communication unit that receives from the connection partner device at least one of a video signal or an audio signal processed by the file or the connection partner device;
At least one of its functions or characteristics for the connection destination device to set a combination of the file received from the connection destination device received by the communication unit or a video signal or audio signal processed by the connection destination device. A control unit that holds the information so that the connection destination device can read the information, and sets operations of the decoder unit, the video processing unit, and the audio processing unit,
An electronic device comprising:   The electronic device according to claim 8, wherein the function or characteristic set by the control unit includes at least an item related to power consumption.   10. The electronic apparatus according to claim 8, wherein the function or characteristic set by the control unit includes at least an item related to the characteristic of the video processing unit.   The electronic device according to claim 8 or 9, wherein the function or characteristic set by the control unit includes at least an item relating to the characteristic of the audio processing unit.   The electronic device according to claim 8, further comprising a control input unit that enables an external setting regarding a function or characteristic set by the control unit. In an output method for outputting video and audio between a transmission-side electronic device and a reception-side electronic device connected by a bidirectional communication interface,
Compare the function or characteristic of the sending device with the function or characteristic of the other device,
Set video data, audio data, video signal and audio signal combination to realize high function or higher characteristics,
A video and audio output method for supplying video and audio from a transmitting device to a receiving device.

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