JP2010122743A - Hdmi receiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily and reliably write firmware data by effectively using even the transmission area of a video signal without using an exclusive apparatus. <P>SOLUTION: An image display device 150 as an HDMI receiver includes: a firmware recording part 504 for recording firmware; an HDMI receiving part 508 for receiving HDMI data having a sound signal, where sound header data and sound firmware data obtained by converting firmware data into a digital sound signal are included, and a video signal including video information concerning the updating of the firmware; a monitor output part 550 for outputting the video signal to a monitor; a header detecting part 552 for detecting the sound header data; a firmware generating part 554; and a firmware updating part 556. The monitor output part outputs the video information concerning the updating of the firmware to the monitor when the firmware is updated. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an HDMI receiving apparatus for updating firmware through HDMI.

  In electric products such as televisions and personal computer monitors, firmware is fixedly incorporated in order to execute basic control of the hardware. If you try to update this firmware to update the function or fix a bug, a general-purpose interface for updating the firmware has not been assumed in the past. It was necessary. However, because there is less demand for update-only devices and production costs and sales prices are higher, when a general user updates the firmware of an electrical product, either purchase an expensive update-only device or install an update-only device. Had to ask a professional contractor to have.

  Therefore, several methods for easily performing firmware update have been proposed. For example, in the HDMI (High-Definition Multimedia Interface) standard, firmware data is written in a data area called InfoFrame, and the firmware data is transmitted from a CD or DVD playback device to a data playback device provided with an HDMI input terminal. A technique for updating the firmware of the data reproducing apparatus is known (for example, Patent Document 1).

Also disclosed is a technique for converting firmware data into image information and transmitting the image data from a CD or DVD playback device to an image playback device through an input terminal such as HDMI (for example, patent document). 2). Furthermore, a technique for transmitting firmware data converted into an audio signal to an electronic device having an input terminal for an audio signal and updating the firmware of the electronic device is also disclosed (for example, Patent Document 3).
Republished 2004-091207 JP 200698774 A JP 2006-155208 A

  However, when the technology described in Patent Document 1 is used, the firmware is accommodated in the InfoFrame. Therefore, in order to correctly transmit the firmware data included in the InfoFrame, a dedicated CD / DVD playback device is required. It was necessary to add a function or manufacture a dedicated playback device, and the firmware could not be updated with a general-purpose playback device. In addition, if an electrical product that is the target of firmware update passes through a repeater device such as an AV amplifier between the CD and DVD playback device on the transmission side, the InfoFrame disappears in the repeater device, so that the InfoFrame is not included in itself. The problem of not reaching was invited.

  Further, in the case of the technique described in Patent Document 2, firmware data is converted into image information and transmitted. This image information is a continuous moving image, and is generally MPEG (Moving Picture Experts Group) -2, MPEG-4. MPEG-4 / AVC (Advanced Video Coding) and the like are subjected to lossy compression. Therefore, on the side of the electrical product that is the firmware update target, there is a possibility that the data after decoding is different from that before decoding within the range allowed as moving image data, that is, the firmware data may not be decoded in a complete form. In normal image data, there is no problem with slight data fluctuations, but firmware data can cause errors.

  In addition, as described above, on the side of an electrical product that is a firmware update target, video and audio signals are simultaneously received in the HDMI standard. However, in the technique described in Patent Document 3, a video signal is not received while firmware data is received as an audio signal. For this reason, in the case of a TV or the like having a function of displaying an image itself, nothing is displayed on the screen and the data transmission area is wasted. In particular, with this technology, firmware data is received as an audio signal, but since it cannot be identified whether the audio signal is normal audio or firmware data, the firmware update to the update target device is correct. May not be executed.

  In view of such problems, the present invention updates firmware data easily and reliably with a general-purpose playback device without using a playback device dedicated to firmware update, and further effectively uses the video signal transmission area to update the firmware. It is an object of the present invention to provide an HDMI data receiving apparatus capable of transmitting alerting and progress during updating to a user.

  In order to solve the above problems, a typical configuration of the HDMI receiving apparatus of the present invention includes a firmware recording unit that records firmware, audio header data that is an audio signal in which a predetermined pattern is continued for a predetermined period, and firmware update. Audio data obtained by converting firmware data to digital audio signals to be arranged in that order, and a video signal including video information related to firmware update reproduced together with the audio firmware data signal, HDMI receiving unit for receiving HDMI data based on HDMI standard, monitor output unit for outputting received video signal to monitor, header detecting unit for detecting audio header data from received audio signal, and audio header data Is detected, its audio header A firmware generation unit that decodes a digital audio signal following the data and generates firmware data, and a firmware update unit that updates the firmware of the firmware recording unit with the generated firmware data, and the monitor output unit At the time of update, video information related to the firmware update is output to the monitor.

  In the present invention, the firmware data can be extracted from the audio firmware data obtained by converting the firmware data into a digital audio signal, and can be reflected in its own firmware recording unit. With such a configuration, the user can update the firmware data of the HDMI receiving apparatus simply by playing a CD, DVD, or the like on which audio firmware data is recorded using a general-purpose playback apparatus. Therefore, the user can write firmware data by using a general-purpose CD or DVD playback device without purchasing a dedicated device or requesting a specialist. In addition, since audio header data indicating a certain offset value that cannot be generated by audio is arranged at the beginning of the HDMI data, it is possible to reliably recognize that firmware data is included. it can.

  Furthermore, in the HDMI standard, for example, firmware is written in the video signal transmitted simultaneously with the audio signal as information relating to the audio firmware data. In response to this, an image for estimating the remaining time until completion of the firmware is received and displayed. This makes it possible to effectively use the transmission area of the video signal that is always ensured simultaneously with the audio signal in the HDMI standard, and provide information useful to the user.

  The HDMI receiving apparatus may further include an audio output unit that outputs the received audio signal, and an audio mute unit that mutes the audio output of the audio output unit when audio header data is detected.

  With this configuration, reproduced audio firmware data different from normal audio data is not output from the speaker, and a more comfortable environment can be provided to the user when updating the firmware data.

  As described above, the present invention updates firmware data easily and surely with a general-purpose playback device without using a dedicated firmware update playback device, and is also updating the firmware by effectively using the video signal transmission area. It is possible to communicate the alerting and progress status to the user.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The dimensions, materials, and other specific numerical values shown in the embodiments are merely examples for facilitating the understanding of the invention, and do not limit the present invention unless otherwise specified. In the present specification and drawings, elements having substantially the same function and configuration are denoted by the same reference numerals, and redundant description is omitted, and elements not directly related to the present invention are not illustrated. To do.

  Conventionally, even if an attempt was made to update the firmware of electrical products such as TVs and monitors to update functions or fix bugs, a general-purpose interface for updating the firmware was not assumed. A dedicated playback device was required.

  In this embodiment, firmware data is easily and reliably updated by a general-purpose playback device without using such a firmware update dedicated playback device, and the firmware update is being performed by effectively using the video signal transmission area. The purpose of this is to convey the user's attention and progress to the user. Here, the entire firmware update system capable of achieving such an object will be described first, and then the specific configuration of the HDMI data generation device, the playback device, and the image display device as the HDMI reception device, and the outline of the firmware recording medium Will be explained.

(First embodiment: Firmware update system 100)
FIG. 1 is an explanatory diagram showing a schematic relationship of the firmware update system. In particular, FIGS. 1A and 1B show schematic relationships of the firmware update systems 100 (100A and 100B) in this embodiment, and FIG. 1C shows a conventional example as a comparative example. The schematic relationship of the firmware update system 10 is shown.

  In FIG. 1C, a firmware update system 10 as a comparative example includes a firmware generation device 12, an arbitrary cable 14, a firmware update dedicated device 16, and an image display device 18. The firmware generation device 12 includes a main body including a central processing unit and HDD, a monitor, a keyboard, and the like. Here, the firmware generation device 12 generates firmware data, and transmits the firmware data to the firmware update dedicated device 16 through the cable 14.

  The firmware update dedicated device 16 transmits the firmware data to be updated to the update target device, here, the image display device 18 through the cable 14 based on the dedicated interface. The image display device 18 updates its own firmware with the acquired firmware data.

  Thus, in the comparative example, in order to update the firmware of the image display device 18, the firmware update dedicated device 16 must be used. In this case, the user requests the service center to update the firmware, and the user cannot easily update the firmware.

  In contrast, the firmware update system 100A according to the present embodiment shown in FIG. 1A includes an HDMI data generation device 110 as an HDMI data generation device and a data recording device, a firmware recording medium 120, a playback device 130, and the like. An HDMI cable 140 compliant with the HDMI standard and an image display device 150 as an HDMI receiving device are configured.

  The HDMI data generation device (data recording device) 110 generates firmware data, converts the firmware data into audio firmware data, and records the audio firmware in the firmware recording medium 120. The firmware recording medium 120 includes a recording medium such as a DVD, a USB (Universal Serial Bus) memory, an SD (Secure Digital) memory card, and a portable HDD (Hard disk drive).

  The playback device 130 is composed of a general-purpose playback device such as a CD player, a DVD player, a Blu-ray disc playback device, or an imaging device (digital camera or video camera) having a playback function of media such as a CD or a DVD. Data read from a medium such as DVD or DVD, in particular, the firmware recording medium 120 is reproduced as a normal audio signal and video signal. The reproduced audio signal and video signal are transmitted to the image display device 150 through the HDMI cable 140.

  The image display device 150 includes a liquid crystal display, an organic EL (Electro Luminescence) display, a plasma display, and the like, and reproduces an image signal and an audio signal input from an HDMI standard connector. In the present embodiment, the image display device 150 updates its own firmware using the audio firmware data received from the HDMI cable 140. Detailed operations relating to the image display device 150 will be described later.

  Further, as in the firmware update system 100B of FIG. 1B, the HDMI data generation device 110 is directly connected to the image display device 150 via the HDMI cable 140 without using the firmware recording medium 120 and the playback device 130, and the audio Firmware data can also be transmitted directly from the HDMI data generation device 110 to the image display device 150.

  Hereinafter, specific configurations of the HDMI data generation device 110, the general-purpose playback device 130, and the image display device 150 serving as the HDMI data reception device constituting the firmware update system 100 will be described.

(HDMI data generation device (data recording device) 110)
FIG. 2 is a block diagram illustrating a configuration of the HDMI data generation device. The HDMI data generation device 110 includes a generation control unit 200, a generation main recording unit 202, a generation operation unit 204, a generation recording I / F unit 206, and an HDMI transmission unit 208.

  The generation control unit 200 manages and controls the entire HDMI data generation device 110 using firmware and programs on a semiconductor integrated circuit including a central processing unit (CPU). The generation main recording unit 202 includes a ROM, a RAM, an EEPROM, a nonvolatile RAM, a flash memory, an HDD, and the like, and records a program processed by the generation control unit 200.

  The generation operation unit 204 includes switches such as a keyboard, a cross key, and a joystick, and receives a user operation input.

  The generation recording I / F unit 206 records data generated by the data generation unit 254 described later on the firmware recording medium 120. The user can easily update the firmware of the image display device 150 to be updated connected to the playback device 130 via the HDMI cable 140 by playing back the firmware recording medium 120 using the general-purpose playback device 130.

  The HDMI transmission unit 208 transmits HDMI data to the image display device 150 through an HDMI terminal (not shown) when the data generated by the data generation unit 254 described later is directly transmitted to the image display device 150.

  The generation control unit 200 also functions as a conversion generation unit 250, a header generation unit 252, and a data generation unit 254.

  The conversion generation unit 250 converts the firmware data for updating the firmware of the image display device (HDMI receiving device) 150 that is the target device into a digital audio signal, and generates audio firmware data. In the present embodiment, a PCM (Pulse Code Modulation) method that is non-compressed and has a small data processing load will be described as an example of a digital method. Can be applied. Also, as the audio firmware data, firmware data is written only in the lower 8 bits without using the upper 8 bits in the PCM 16-bit data. With this configuration, even if a non-compliant device that is not compatible with the firmware data update in this embodiment recognizes the voice firmware data as a voice and plays it as a voice as it is, a loud voice data is played back. The situation where it is done can be avoided.

  The header generation unit 252 generates audio header data that is an audio signal in which a predetermined pattern, for example, 0x0001 (numbers after “0x” means a hexadecimal number) or 0x0002 is continued for a predetermined period, for example, 2 seconds. Such audio signals can be set to 0x0001 in the first half of the predetermined period and 0x0002 in the second half, or the arrangement order can be reversed. Similarly to the audio firmware data, the audio header data uses only the lower 8 bits without using the upper 8 bits in the PCM 16-bit data.

  The data generation unit 254 has the audio header data generated by the header generation unit 252 and the audio firmware data generated by the conversion generation unit 250 arranged in that order as an audio signal, and is reproduced as a video signal together with the audio firmware data signal. HDMI data based on the HDMI standard is generated as data having video information related to the firmware update, for example, video information indicating alerting and progress during firmware update. In the present embodiment, the HDMI data based on the HDMI standard has been described as an example. However, in the data generation device 110 as the data recording device, the data generated by the data generation unit 254 is not limited to the HDMI standard, Any data based on a standard in which video is transmitted simultaneously may be used.

  In this embodiment, since the firmware data is converted into a digital audio signal, the user can record the firmware data (audio firmware data) converted into the audio signal on a CD or DVD as described above. The firmware data can be written using the playback device 130 such as a general-purpose CD or DVD without purchasing a dedicated device and without requesting a specialized supplier.

  Moreover, since audio header data indicating a predetermined offset value that is an audio signal method but cannot be generated by audio is arranged at the beginning of the HDMI data, firmware is stored in the image display device 150 that is an electronic product to be updated. Recognize that data is included.

  Further, in the HDMI standard, information regarding audio firmware data is transmitted to a video signal transmitted simultaneously with an audio signal, for example, a warning is issued so that the power is not turned off because the firmware is written, and depending on the progress status. And put a video to estimate the remaining time until firmware completion. This makes it possible to effectively use the transmission area of the video signal that is always ensured simultaneously with the audio signal in the HDMI standard, and provide information useful to the user.

(HDMI data generation method)
Next, an HDMI data generation method using the above-described HDMI data generation device 110 will be described.

  FIG. 3 is a flowchart showing a process flow of the HDMI data generation method. The conversion generation unit 250 of the HDMI data generation apparatus 110 generates audio firmware obtained by converting firmware data for updating the firmware of the image display apparatus 150 that is the target device into a PCM audio signal (S300). Then, the header generation unit 252 generates audio header data that is an audio signal in which a predetermined pattern is continued for a predetermined period (S302). Thereafter, the data generation unit 254 arranges audio header data and audio firmware data in that order as audio signals, and generates HDMI data to which video information related to audio firmware data is added as video signals (S304). Then, in response to a user operation input, the generation recording I / F unit 206 records the generated HDMI data in the firmware recording medium 120 (S306). Here, instead of the firmware recording medium 120, the HDMI transmission unit 208 can directly transmit the generated HDMI data to the image display device 150 via the HDMI cable 140.

  The firmware recording medium 120 generated by such a method is played back on the general-purpose playback device 130 and transmitted to the image display device 150 to be updated via the HDMI cable 140, thereby updating the firmware of the image display device 150. . This makes it possible to update firmware data easily and reliably with a general-purpose playback device without using a dedicated playback device for firmware update, and also to alert and progress during firmware update by effectively using the video signal transmission area. Can be communicated to the user.

(Firmware recording medium 120)
Next, the firmware recording medium 120 generated using the above-described HDMI data generation method will be described.

  As described above, the firmware recording medium 120 is composed of a recording medium such as a DVD, a USB memory, an SD memory card, and a portable HDD, and as audio signals, audio header data that is an audio signal obtained by continuing a predetermined pattern for a predetermined period of time, , The firmware data for updating the firmware of the target device becomes audio firmware data converted into digital audio signals and the header data of the audio firmware data, and the subsequent audio signal is the firmware data for update Audio header data, which is an audio signal in which a predetermined pattern for causing the device to recognize is continued for a predetermined period, is recorded, and video information related to audio firmware update is reproduced as an audio signal along with the audio firmware data signal. Recorded . Here, as a digital method, a PCM method that is not compressed and has a small data processing load will be described as an example, similarly to the HDMI data generation device 110. Can be applied to.

(Reproducing device 130)
FIG. 4 is an external view showing an example of an imaging apparatus as a playback apparatus. 4A shows a so-called digital camera, and FIG. 4B shows a video camera. The playback device (imaging device) 130 is portable and includes a main body 402, an imaging lens 404, an imaging operation unit 406, and a viewfinder 408.

  The main body 402 records the image signal captured through the imaging lens 404 so that it can be viewed again, and adjusts the recording timing and angle of view in accordance with user input to the imaging operation unit 406. Further, it accepts an input of switching between imaging modes such as outdoor, indoor, night view, etc. from the user, and executes processing corresponding thereto. At the time of imaging, the user can view the image signal that is actually recorded with reference to the image displayed on the viewfinder 408, and can capture the subject at a desired position and occupied area. The viewfinder 408 is configured by a liquid crystal display, an organic EL display, or the like.

  FIG. 5 is a block diagram showing the configuration of the playback apparatus. Here, an imaging device (video camera) is cited as the playback device 130. The reproduction apparatus 130 includes an imaging unit 420, a signal processing unit 422, an image recording unit 424, an imaging operation unit 406, an image processing unit 426, an imaging recording I / F unit 428, an image output unit 430, and an imaging unit. A control unit 432 and an imaging main recording unit 434 are configured.

  The imaging unit 420 images a subject and generates an image signal. The signal processing unit 422 forms a luminance signal or a color signal with respect to the input signal and stores it in the image recording unit 424. The image recording unit 424 includes a buffer memory such as SDRAM (Synchronous-DRAM), and temporarily records image data. The imaging operation unit 406 includes operation keys including a release switch, a cross key, a joystick, and the like, and accepts a user operation input. The image processing unit 426 compresses the image signal from the image recording unit 424 to generate recording image data, and decompresses the image data when reproducing the view image or recording data to be displayed on the viewfinder 408. To do.

  The imaging / recording I / F unit 428 records the recording signal (data stream) encoded through the image processing unit 426 on an arbitrary recording medium. As an arbitrary recording medium, an optical disk medium such as a DVD or a BD, a medium such as a RAM, an EEPROM, a nonvolatile RAM, a flash memory, or an HDD can be applied. Further, this recording medium includes the firmware recording medium 120 generated by the above-described HDMI data generation apparatus 110, and the imaging recording I / F unit 428 can also read the HDMI data from the firmware recording medium 120.

  The image output unit 430 includes a D / A converter, processes the digital image signal acquired from the image recording unit 424 into a viewable image signal, and outputs the image signal to the viewfinder 408. Further, since the image output unit 430 has a video terminal for outputting an image to the outside, it can be connected to various image display devices such as a separate monitor. In the present embodiment, the image output unit 430 is connected to the image display device 150 as an HDMI data receiving device, and transmits the HDMI data read from the firmware recording medium 120 by the imaging recording I / F unit 428. The audio data of the HDMI data includes firmware data (audio firmware data) converted into an audio signal.

  The imaging control unit 432 manages and controls the entire playback device 130 using a semiconductor integrated circuit, and executes various calculations necessary for imaging and the like. The imaging main recording unit 434 records programs and the like processed by the imaging control unit 432.

  FIG. 6 is an explanatory diagram showing another example of the firmware update system. When the playback device 130 plays back the firmware recording medium 120, the playback device 130 outputs HDMI data, that is, audio header data and audio firmware data as audio signals, and video information as video signals through the HDMI connector. By transmitting firmware data as an audio signal in this way, even if a repeater device such as an AV amplifier 160 is connected between the playback device 130 and the image display device 150 as in the firmware update system 100C of FIG. The firmware data is not affected by any loss or the like, and the firmware data can be reliably transmitted to the image display device 150 to be updated.

(Image display device 150)
Next, the image display apparatus 150 according to the first embodiment as an HDMI data receiving apparatus capable of updating firmware using the HDMI data generated using the HDMI data generation method will be described.

  FIG. 7 is a functional block diagram showing a hardware configuration of the image display apparatus according to the first embodiment. The image display device 150 includes a display control unit 500, a display main recording unit 502, a firmware recording unit 504, a display operation unit 506, an HDMI receiving unit 508, a monitor 510, and a speaker 512 as an audio output unit. Consists of including.

  The display control unit 500 manages and controls the entire image display device 150 using firmware and a program on a semiconductor integrated circuit including a central processing unit (CPU). The display main recording unit 502 includes a ROM, a RAM, an EEPROM, a nonvolatile RAM, a flash memory, an HDD, and the like, and records a program processed by the display control unit 500.

  The firmware recording unit 504 is composed of an EEPROM, and fixedly records firmware data of the image display device 150 generated by a firmware generation unit 554 described later. Further, in the firmware recording unit 504, a writing program used when a firmware update unit 556 described later records and updates firmware data in the firmware recording unit 504 is recorded in an unrenewable manner. When the image display device 150 is started or restarted, the display control unit 502 reads the firmware recorded in the firmware recording unit 504 and controls the entire image display device 150 according to the read firmware.

  The display operation unit 506 is configured by a button switch, and performs operation input from the user when performing calibration which is adjustment of display quality such as brightness, contrast, gamma value, and color adjustment in addition to power ON / OFF. Accept.

  The HDMI receiving unit 508 includes audio header data that is an audio signal in which a predetermined pattern is continued for a predetermined period, and audio firmware data obtained by converting firmware data for updating firmware into a digital audio signal in that order. HDMI data based on the HDMI standard is received, which includes an audio signal and a video signal including video information related to firmware update reproduced together with the audio firmware data signal.

  The monitor 510 displays a video based on the video signal received by the HDMI receiving unit 508 under the control of the monitor output unit 550 described later. In this embodiment, a liquid crystal display is used as an example of the monitor 510. However, the monitor 510 is not limited to a liquid crystal display, and an organic EL display, a cathode ray tube monitor, or the like can also be applied. The speaker 512 converts the audio signal received by the HDMI receiving unit 508 into physical vibration and outputs it as audio.

  The display control unit 500 also functions as a monitor output unit 550, a header detection unit 552, a firmware generation unit 554, a firmware update unit 556, and an audio mute unit 558.

  The monitor output unit 550 outputs the video signal received by the HDMI receiving unit 508 to the monitor 510. Further, the monitor output unit 550 outputs video information related to the firmware update to the monitor 510 when the firmware is updated.

  The header detection unit 552 detects audio header data from the audio signal received by the HDMI reception unit 508.

  When the header detection unit 552 detects audio header data, the firmware generation unit 554 decodes a PCM audio signal that follows the audio header data, and generates firmware data.

  The firmware update unit 556 updates the firmware of the firmware recording unit 504 with the firmware data generated by the firmware generation unit 554.

  The audio mute unit 558 mutes the audio output of the speaker 512 when a DC (Direct Current) start header (hereinafter, audio header data is referred to as a DC start header) as audio header data is detected. When the header detection unit 552 detects a DC end header from the received audio signal or the reception of the audio signal is interrupted, the audio mute unit 558 cancels the mute of the audio output. With this configuration, reproduced audio firmware data different from normal audio data is not output from the speaker 512, and a more comfortable environment can be provided to the user when updating the firmware data. Details of the DC start header and the DC end header will be described later.

  Note that, as described above, even if the audio firmware data is directly reproduced as an audio signal and output from the speaker, the audio firmware data is not reproduced at a high volume. Therefore, this audio mute function may be provided as necessary.

  Subsequently, a transmission procedure of HDMI standard data between the playback device 130 and the image display device 150 will be described.

  FIG. 8 is an explanatory diagram for explaining transmission of data of the HDMI standard. Here, the HDMI data is transmitted from the HDMI source 600 of the playback device 130 to the HDMI sink 604 of the image display device 150 through the transmission path 602. The transmission path 602 uses high-speed differential transmission that transmits the same electrical signal in opposite phase to two parallel cables.

  The audio / control signal (audio signal) 606 is transmitted to a TMDS (Transition Minimized Differential Signaling) encoder 612 together with a video signal through packetization processing by the packetization processing unit 608, and is encoded according to the control signal 614. Then, after being sent to the TMDS decoder 618 via the TMDS channel (TMDS channels 0 to 2) 616 and decoded by the TMDS decoder 618, the audio signal is restored by the packet restoration processing unit 620, and the image display device 150 together with the video signal is restored. Is transmitted to each part.

  In addition to the TMDS channel 616, the transmission path 602 includes a TMDS clock channel 622, a display data channel (DDC) 626, a hot plug detect 628, a consumer electronics control (CEC) 630, and the like. . The TMDS clock channel 622 transmits a reference clock used for decoding by the TMDS decoder 618. The display data channel 626 is used when the HDMI source 600 reads out the specification data (EDID (Extended Display Identification Data)) of the HDMI sink 604 from the EDID ROM 624 and further authenticates HDCP (High-bandwidth Digital Content Protection). Is done. The hot plug detect 628 is used to perform an automatic environment setting function such as plug and play. The consumer electronics control 630 is used to remotely control the HDMI sink 604 device.

  In the present embodiment, the packetization processing unit 608 converts the audio firmware data and the DC start header into packets. Then, in the same manner as described above, it is transmitted as HDMI data to the TMDS decoder 618 of the HDMI sink 604 using the TMDS channel 616 together with the video signal related to the audio firmware data via the TDMS encoder 612. The HDMI sink 604 generates an audio signal from the received HDMI data and uses it together with the video signal for updating the firmware.

  FIG. 9 is an explanatory diagram of HDMI data transmitted for firmware update according to the first embodiment. 9A shows the data type of the audio firmware data, FIG. 9B shows the structure of the HDMI data in time series, and FIG. 9C shows the HDMI data of the image display device 150. FIG. 9D shows a display example of the monitor 510 during reception of HDMI data.

  As shown in FIG. 9A, in this embodiment, the audio firmware data is formed by 2ch PCM method, 48 kHz, 16 bit data that is most often used as an audio signal so as not to limit the type of the playback device 130. .

  In FIG. 9 (b), the audio signal of the HDMI data received by the HDMI receiving unit 508 is composed of a DC start header, audio firmware data, DC end header, and update end audio data at the start of reception 700, each at the start of reception. 700, data reception & firmware update in progress 702, and update end timing 704 are formed. The DC start header and the DC end header will be described in detail later.

  Also, the HDMI receiving unit 508 receives the updating video data as a video signal from the reception start time 700 to the data reception & firmware updating 702.

  As shown in FIG. 9C, when the header detection unit 552 of the image playback device 150 detects the DC start header, the audio mute unit 558 is connected to the speaker 512 while the audio firmware data is being received. Mute the audio output. Subsequently, when the header detection unit 552 detects a DC end header to be described later, the audio mute unit 558 releases the mute. Then, a warning sound for notifying that the firmware is to be updated, for example, a beep sound, is output to the speaker 512 as the end sound.

  Further, as shown in FIG. 9D, the monitor 510 has a display area for the video 750 that outputs the input video signal and an area for displaying the video 752 such as the result of the dynamically generated firmware update process. Divided. As shown in FIG. 9C, in the display area of the video 750, as the video that is being updated, the firmware update is performed, for example, a warning video that notifies the user not to turn off the power, and the like, and the video 752 is displayed. In the area, information indicating the success or failure of the firmware update, such as “Update process completed successfully”, “A new version has already been written”, “Update process failed”, etc. at the end of update 732 Display a message.

  Meanwhile, as internal processing, during data reception & firmware update 730, the HDMI reception unit 508 receives the audio firmware data, and the firmware generation unit 554 generates firmware data from the received audio firmware data as needed. The firmware update unit 556 updates the firmware as needed with the firmware data generated by the firmware generation unit 554.

  Further, at the end of update 732, an end sound for informing that the firmware update has been completed is output from the speaker 512, and at the same time, an update end image for informing that the firmware update has been completed is displayed as an image on the monitor 510. Output to the display area 752. Then, after detecting the DC end header, the end sound and the end video are reproduced for a predetermined time.

  As described above, in the HDMI standard, for example, firmware is written in the video signal transmitted simultaneously with the audio signal as information related to the audio firmware data. Receives and displays a video that estimates the remaining time until firmware completion depending on the situation. This makes it possible to effectively use the transmission area of the video signal that is always ensured simultaneously with the audio signal in the HDMI standard, and provide information useful to the user.

  FIG. 10 is an explanatory diagram for explaining the format of audio firmware data. The format item name 800, size 802, and summary 804 are summarized in a table. In the present embodiment, as described in the description of the HDMI data generation device 110, the upper 8 bits are used for the audio firmware data in the PCM 16-bit data, and the firmware data is written only in the lower 8 bits (in the figure, 16 bits). (8) indicates that the lower 8 bits of 16 bits are used). With this configuration, even if a non-compliant device that is not compatible with the firmware data update in this embodiment recognizes the voice firmware data as a voice and plays it as a voice as it is, a loud voice data is played back. The situation where it is done can be avoided.

  In the DC start header of FIG. 10, the playback apparatus 170 can detect the start point of the audio firmware data by continuing the value of the predetermined pattern with the audio signal for 2 seconds, for example. The value of the predetermined pattern is a value that cannot occur in a normal audio signal, such as continuous 0x0001 (16-bit value). By using such a predetermined pattern value, it is possible to reliably recognize that the subsequent data is audio firmware. Similarly to the DC start header, the DC end header can reliably recognize that the transmission of the audio firmware has been completed.

  The data block length designates the length of a data block in which audio firmware data is stored. Here, the length of the data block is specified using 4 bytes in an LSB (Least Significant Byte) First (read from the least significant byte) method. In FIG. 10, “0x00E8, 0x0003, 0x0000, 0x0000” is indicated as an example of specifying 1000 words (1000 × 16 bits). When the lower 8 bits are read by LSBFirst, “3E8” is obtained, which means 0x03E8 in hexadecimal and 1000 in decimal.

  In the table of FIG. 10, the manufacturer code, the model code, the checksum, and the like are shown as the firmware data format, but it goes without saying that the items are not limited to such items.

  Further, these data are biased in the positive direction with respect to the 0 level (0x0000). Therefore, the center value 0x0080 of 0x00FF, which is the maximum value of the lower 8 bits to be used among the 16-bit values, is subtracted from the data before being transmitted as audio firmware data. Then, the image display device 150 restores the original data by adding 0x0080 to each 16-bit value of the received audio firmware data. However, with respect to items such as the DC start header and the DC end header that require the value of the predetermined pattern to continue, the value of the predetermined pattern is changed, so that 0x0080 addition and subtraction are not performed.

  By performing such processing, the center of the firmware data to be transmitted can be brought close to the 0 level, and even if a non-compatible device such as the one described above misrecognizes it as a normal audio signal and reproduces it, The volume can be further reduced.

  Furthermore, for example, in the case where firmware data includes a data table and there is a possibility that the value of 0x0001 is continuously mistaken as a DC start header or a DC end header, RLL (Run-Length Limited coding) encoding is performed. To reduce the continuation of 0 in advance. By performing such processing, misidentification can be prevented and malfunction during firmware update can be prevented.

  As described above, in this embodiment, the firmware data can be extracted from the audio firmware data obtained by converting the firmware data into a digital audio signal and reflected in the firmware recording unit 504 of the firmware data. With this configuration, the user can update the firmware data of the image display device 150 as the HDMI receiving device only by playing back a CD, DVD, SD card or the like on which the audio firmware data is recorded using the general-purpose playback device 130. can do. Accordingly, the user has a CD player, a DVD player, a Blu-ray disc playback device, or a playback function of a medium such as a CD or a DVD, without purchasing a dedicated device or requesting a specialist. Firmware data can be written using a general-purpose playback device 130 such as an imaging device (digital camera or video camera). Also, since a DC start header indicating a certain offset value that cannot be generated by sound is arranged at the beginning of the HDMI data, it is possible to reliably recognize that firmware data is included. it can.

(HDMI data receiving method)
Next, an HDMI data receiving method using the image display device 150 described above will be described.

  FIG. 11 is a flowchart illustrating the processing flow of the HDMI data receiving method according to the first embodiment.

  When the header detection unit 552 of the image display device 150 detects a DC start header in which a predetermined pattern continues for a predetermined period in an audio signal received from the playback device 130 via the HDMI cable 140 (S900 YES), the audio mute unit 558 The audio output of the speaker 512 is muted, and the reproduction of the updating video data by the video signal received by the monitor 510 is started (S902). Then, while the HDMI reception unit 508 receives the audio firmware data, the firmware generation unit 554 generates firmware data from the received audio firmware data as needed, and the firmware update unit 556 stores the firmware according to the generated firmware data. The firmware data of the unit 504 is updated as needed (S904). When the update of the firmware data is completed, the audio output is unmuted and the video is stopped (S906).

  By updating the firmware of the image display device 150 using such a method, the firmware data can be updated easily and reliably by a general-purpose playback device without using a playback device dedicated to firmware update, and the video signal transmission area can be further increased. Can also be used effectively to inform the user of alerts and progress during firmware update.

(Second Embodiment: Image Display Device 1050)
In the first embodiment described above, the firmware is directly updated using the data received by the image display device 150. However, in the second embodiment, the image display device 1050 temporarily holds the audio firmware data, and the audio firmware is updated. After confirming that the data is correct, update the firmware. The specific configuration of the image display device 1050 will be described below in the same procedure as in the first embodiment, and then the HDMI data receiving method will be described. However, elements having substantially the same functions and configurations as those described in the first embodiment are denoted by the same reference numerals, and redundant description is omitted.

  FIG. 12 is a functional block diagram illustrating a hardware configuration of the image display apparatus according to the second embodiment. The image display device 1050 includes a display control unit 1000, a display main recording unit 502, a firmware recording unit 504, a display operation unit 506, an HDMI receiving unit 508, a monitor 510, a speaker 512, and a buffer recording unit 1014. It is comprised including. The display main recording unit 502, the firmware recording unit 504, the display operation unit 506, the HDMI receiving unit 508, the monitor 510, and the speaker 512, which have already been described as the constituent elements in the first embodiment, are substantially Since the functions are the same, repeated description is omitted, and here, the display control unit 1000 and the buffer recording unit 1014 having different configurations will be described.

  Similar to the display control unit 500 of the first embodiment, the display control unit 1000 manages and controls the entire image display device 150 using firmware and programs on a semiconductor integrated circuit including a central processing unit (CPU). The display control unit 1000 also functions as a monitor output unit 550, a header detection unit 552, a firmware generation unit 1054, a firmware update unit 556, and an audio mute unit 558. Again, the redundant description of the monitor output unit 550, the header detection unit 552, the firmware update unit 556, and the audio mute unit 558 already described in the first embodiment is omitted, and the firmware generation unit 1054 is mainly described. To do.

  The buffer recording unit 1014 includes a buffer memory such as SDRAM, and when the header detection unit 552 detects a DC start header, it temporarily records a PCM format audio signal up to the DC end header following the DC start header.

  The firmware generation unit 1054 decodes the PCM audio signal recorded in the buffer recording unit 1014, performs an error check using a checksum or the like, and generates firmware data if there is no abnormality. If there is an abnormality, the audio signal in the buffer recording unit 1014 is deleted, and firmware data is not generated.

  FIG. 13 is an explanatory diagram of HDMI data transmitted for firmware update according to the second embodiment. In particular, FIG. 13A shows the configuration of the HDMI data in time series, and FIG. 13B shows the output status and processing status of the HDMI data of the image display device 1050. Here, portions that are the same as those described in the description of the HDMI data in the first embodiment are omitted, and different configurations and processing are mainly described.

  In FIG. 13 (a), unlike FIG. 9 (b), the firmware update is performed while the audio firmware data is being received (data reception 1102) following the reception start time 1100 for detecting the DC start header. Do not do. Then, after detecting the DC end header, the firmware generation unit 1054 updates the firmware (becomes updating firmware 1104). At this time, the updating voice data is received as a voice signal.

  Also, as shown in FIG. 13B, after the header detection unit 552 of the image playback device 1050 detects a DC start header as a DC start header described later, at the time of data reception 1130, the HDMI reception unit 508 The firmware data is received, and the received audio firmware data is temporarily recorded in the buffer recording unit 1014. When the header detection unit 552 detects the DC end header and finishes receiving the audio firmware data, the firmware generation unit 1054 performs an error check on the received audio firmware data using a checksum or the like. The firmware data is generated from the voice firmware data.

  Subsequently, the firmware update unit 556 updates the firmware with the firmware data generated by the firmware generation unit 1054 (during firmware update 1132). At this time, for example, a beep sound is output from the speaker 512 as the updating voice. At the end of update 1134, as in the first embodiment, an end video notifying that the firmware update has ended is output to the display area of the video 752 of the monitor 510.

In this way, unlike the first embodiment, the audio firmware data is temporarily recorded in the buffer recording unit 1014 until all of the audio firmware data is completely received. Then, the firmware generation unit 1054 performs an error check such as a checksum using the entire received audio firmware data. The firmware is updated only when there is no error. With such a configuration, the error detection becomes more accurate, the situation where the firmware is updated using the erroneous voice firmware data can be avoided, and the firmware can be updated more reliably.
(HDMI data receiving method)

  Next, an HDMI data receiving method using the above-described image display device 1050 will be described.

  FIG. 14 is a flowchart illustrating the processing flow of the HDMI data receiving method.

  When the HDMI receiving unit 508 receives the HDMI data (S1200 YES) and the header detection unit 552 detects the DC start header from the received HDMI data audio signal (S1202 YES), the audio mute unit 558 mutes the audio output and receives it. The stored audio signal starts to be accumulated (S1204). If no DC start header is detected (NO in S1202), video and audio are played as usual (S1206).

  If the model code indicating the model of the target device included in the received header matches that of the own device (YES in S1208), reception of the data of the length specified in the header and other HDMI data is completed, and the header When the detection unit 552 detects a DC end header from the received audio signal (YES in S1210), the audio mute unit 558 cancels the mute of the audio output, reproduces the updating audio, and stops the accumulation of the received audio signal ( S1212).

  The accumulated bit sequence of the audio signal is arranged as a matrix, and an error check is performed on the entire audio firmware data by determining whether there is any data abnormality by a checksum in each of the row direction and the column direction (S1214). If there is no abnormality (YES in S1214), the firmware generation unit 554 generates firmware data from the accumulated audio signal, and the firmware update unit 556 updates the firmware (S1216). If there is an abnormality (NO in S1214), the firmware is not updated.

  When the own device and the model code indicating the model of the target device included in the received header do not match (NO in S1208) and the own device is a repeater device (YES in S1218), the received audio signal is ahead (downstream) of the own device. Transfer to another apparatus (S1220). When the own device is not a repeater device (NO in S1218), the monitor output unit 550 outputs to the monitor 510 and notifies that the own device is not an update target by the firmware data included in the HDMI data (S1222).

  Then, when reception of the data of the length specified for the header and other HDMI data is completed and the header detection unit 552 detects a DC end header from the received audio signal, or reception of the HDMI data is completed. When interrupted (YES in S1224), the mute of the audio output is canceled and the accumulation of the received audio signal is stopped (S1226).

  Finally, regardless of the success or failure of the firmware update, the accumulated audio signal is deleted, the video is stopped, and if the audio is output, the audio is also stopped (S1228), and the process is terminated.

  As described above, in the HDMI data receiving method of the present embodiment, the audio firmware data is temporarily recorded in the buffer recording unit 1014 until the reception of all the audio firmware data is completed. Then, the firmware generation unit 1054 performs an error check such as a checksum using the entire received audio firmware data. The firmware is updated only when there is no error. With such a configuration, it becomes possible to detect errors more accurately, avoid a situation where firmware is updated using erroneous voice firmware data, and firmware data can be updated more reliably.

  As mentioned above, although preferred embodiment of this invention was described referring an accompanying drawing, it cannot be overemphasized that this invention is not limited to this embodiment. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the technical scope of the present invention. Understood.

  Note that each step in the HDMI data generation method and the HDMI data reception method of the present specification does not necessarily have to be processed in time series in the order described in the sequence diagram, and may include processing in parallel or by a subroutine. .

  The present invention can be used in an HDMI receiving apparatus for updating firmware through HDMI.

It is explanatory drawing which showed the schematic relationship of the firmware update system. It is a block diagram which shows the structure of an HDMI data generation apparatus. It is the flowchart which showed the flow of the process of the HDMI data generation method. It is the external view which showed an example of the imaging device as a reproducing | regenerating apparatus. It is a block diagram which shows the structure of the imaging device as a reproducing | regenerating apparatus. It is explanatory drawing which showed the other example of the firmware update system. 1 is a functional block diagram showing a hardware configuration of an image display device according to a first embodiment. It is explanatory drawing explaining transmission of the data of HDMI specification. It is explanatory drawing of the HDMI data transmitted for firmware update. It is explanatory drawing explaining the format of audio | voice firmware data. It is a flowchart explaining the flow of a process of the HDMI data receiving method concerning 1st Embodiment. It is a functional block diagram showing a hardware configuration of an image display device according to a second embodiment. It is explanatory drawing of the HDMI data transmitted for the firmware update concerning 2nd Embodiment. It is a flowchart explaining the flow of a process of the HDMI data receiving method concerning 2nd Embodiment.

Explanation of symbols

110 ... HDMI data generation device (data recording device)
120: Firmware recording medium 150, 1050 ... Image display device (HDMI receiving device)
250 ... Conversion generation unit 252 ... Header generation unit 254 ... Data generation unit 350 ... Conversion generation unit 352 ... Header generation units 354, 1054 ... HDMI data generation unit (data generation unit)
504 ... Firmware recording unit 510 ... HDMI receiving unit 514 ... Speaker (audio output unit)
550 ... Monitor output unit 552 ... Header detection unit 554 ... Firmware generation unit 556 ... Firmware update unit 558 ... Audio mute unit

Claims (2)

A firmware recording unit for recording firmware;
An audio signal comprising audio header data, which is an audio signal obtained by continuing a predetermined pattern for a predetermined period, and audio firmware data obtained by converting firmware data for updating the firmware into a digital audio signal, in that order, and An HDMI receiving unit for receiving HDMI data based on the HDMI standard, the video signal including video information related to the firmware update reproduced together with the audio firmware data signal;
A monitor output unit for outputting the received video signal to a monitor;
A header detector for detecting the voice header data from the received voice signal;
When the audio header data is detected, a firmware generation unit that decodes a digital audio signal following the audio header data and generates firmware data;
A firmware update unit that updates firmware of the firmware recording unit with the generated firmware data;
With
The HDMI receiving apparatus, wherein the monitor output unit outputs video information related to the firmware update to the monitor when the firmware is updated. An audio output unit for outputting the received audio signal;
An audio mute unit for muting the audio output of the audio output unit when the audio header data is detected;
The HDMI receiving device according to claim 1, further comprising:

Images