JP2008258697A - Transmission processor and transmission processing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform authentication processing on a transmitting equipment side as usual and to notify a user of failure in authentication using a user interface that a receiving equipment side normally has even when the transmitting equipment side has no display panel etc. <P>SOLUTION: Disclosed is a transmission processor which performs authentication processing for a receiving device prior to transmission of transmission data and transmits transmission data to correctly be reproduced by the receiving device to the receiving device when the authentication is successful. When the authentication for the receiving device ends in failure, on the other hand, the failure in authentication is reported to the user and message information which can be reproduced out by the receiving device are transmitted to the receiving device. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a transmission processing apparatus and a transmission processing method suitable for application to transmission of, for example, copyright protected information.

  In the transmission of digital image (or digital video) data and audio data, measures for copyright protection are taken.

  For example, there is known a CGMS (Copy Generation Management System) system in which copy restriction information is added as additional information to data to be transmitted. In this CGMS system, for example, if the receiving device side is a recording device and the copy restriction information is extracted from the received data and analyzed, the copy of the received data is not performed. Measures have been taken, such as replacement with data that is not normally reproduced even if it is reproduced (see, for example, Patent Document 1 (Japanese Patent No. 3865382) and Patent Document 2 (Japanese Patent Laid-Open No. 2003-189232)).

  By the way, in recent years, various electronic devices compliant with high-speed digital interface standards such as HDMI (High Definition Multimedia Interface) standard and DVI (Digital Visual Interface) standard have been developed.

  These high-speed digital interface standards employ a TMDS (Transmission Minimized Differential Signaling) serial transmission method, and additional information such as duplication control information such as the CGMS method described above cannot be added to transmission data. It has become a standard.

  In these high-speed digital interface standards, HDCP (High-bandwidth Digital Content Protection) technology is used as a copyright protection technology.

  That is, as will be described in detail later, in this HDCP technology, each of the transmitting device side and the receiving device side has keys for encryption and decryption, and predetermined keys using these keys are used. By executing the calculation, authentication processing is performed on the transmitting device side to confirm that the receiving device is not an unauthorized device. When this authentication process can authenticate that the receiving device is not an unauthorized device (hereinafter referred to as “authentication succeeded” or “successful authentication”), transmission data is encrypted and transmitted from the transmitting device side. Can be received and decoded on the side (see, for example, Japanese Patent Application Laid-Open No. 2006-246300).

The above-mentioned patent documents are as follows.
Japanese Patent No. 3865382 JP 2003-189232 A JP 2006-246300 A

  By the way, in the above HDCP technology, when it is not possible to authenticate that the receiving device is not an unauthorized device by the authentication processing for the receiving device (hereinafter referred to as authentication failure or authentication failure), conventionally, In general, the transmitting device performs processing such as attempting authentication again or canceling data transfer.

  However, the authentication procedure is not simple, and the authentication process is divided into a plurality of steps and takes time, so when repeating authentication again, a long waiting time that the cause is unknown to the user continues, There is a problem that can lead to confusion.

  Further, when the data transfer is stopped, a display for display or a dedicated LED (Light Emitting Diode) exists on the transmitting device side, and means for notifying the user of the authentication failure is provided. For example, the user can know the authentication failure. However, transmission devices that do not have their display panels, dedicated LEDs, and notification means, and devices that do not have display displays, dedicated LEDs, and notification means in order to increase costs when they are installed, and as a design In a device that does not want to provide an authentication failure notification display or LED, similarly to the above, there is a problem that the user cannot recognize the authentication failure and may cause confusion.

  Further, in the above-mentioned Patent Document 3, normally, what determines whether authentication is successful on the transmitting device side is configured to determine whether authentication is successful on the receiving device side, It is described that when the authentication is unsuccessful, the user is notified using a user interface such as a display for display which is normally provided on the receiving device side.

  However, in this case, there is a problem that the configuration on the receiving device side is different from the normal one, and there is a problem that a means for judging whether or not the authentication has been established must be provided. Other than receiving devices that do not have authentication means, there is a problem that the above-described problem cannot be avoided even if a user interface such as a display for display is equipped as standard.

  Although the above points out problems when using HDCP technology for HDMI and DVI transmission, this problem is not limited to HDCP technology alone.

  For example, in the IEEE (The Institute Electrical and Electronics Engineers, Inc.) 1394-DTCP (Digital Transmission Content Protection) method, an authentication function and an authentication function are provided when an authentication function and a key are used. Copyright protection can be realized by encrypting and transmitting data requiring copyright protection such as data and audio data.

  As described above, the IEEE 1394-DTCP system encrypts video data and audio data when it is necessary to protect the copyright when transmitting video data and audio data. In the case of failure, the same problem as described above occurs.

  In view of the above points, the present invention performs authentication processing on the transmitting device side as usual, and is normally equipped on the receiving device side even if the transmitting device side is not equipped with a display panel or the like. It is an object of the present invention to notify a user of an authentication failure using a user interface.

In order to solve the above problems, the present invention provides:
Prior to transmission of transmission data, when the authentication process is successful for the connected receiving device, and when the authentication is successful, the transmission processing device transmits transmission data that can be correctly reproduced by the receiving device to the receiving device,
When authentication for the receiving device fails, message information that can be reproduced and output by the receiving device for notifying the user that the authentication has failed is transmitted to the receiving device. Providing equipment.

  According to this configuration of the present invention, when the authentication of the receiving device fails, the transmission processing device is a message that can be reproduced and output by the receiving device, and notifies the user of the authentication failure. Is sent to the receiving device.

  Therefore, the user can recognize the authentication failure by the message reproduced and output by the receiving apparatus, and there is no confusion. In this case, it is not necessary to provide a display for display in the transmission processing device, and it is not necessary to provide authentication means as in Patent Document 3 on the receiving device side. Can be used to notify the user of an authentication failure.

  According to the present invention, as usual, a user who performs authentication processing on the transmission processing device side and is equipped as standard on the reception device side even if the transmission processing device side is not equipped with a display for display or the like. Using the interface, the user can be notified of the authentication failure.

  Hereinafter, embodiments of a transmission processing apparatus according to the present invention will be described with reference to the drawings.

  FIG. 1 includes a transmission processing device 10 according to an embodiment of the present invention and a reception processing device 20 that receives transmission data from the transmission processing device 10. The transmission processing device 10 and the reception processing device 20 are 2 shows an example of the configuration of a transmission / reception system connected by an HDMI transmission line 30 composed of a single standard cable (hereinafter referred to as an HDMI cable).

  In the example of FIG. 1, the transmission processing device 10 is configured as a DVD (Digital Versatile Disc) player, and compressed video data, compressed audio data, and the like from a DVD 11 loaded in a DVD loading unit (not shown). A read-out unit 12 that reads out the compressed data, a decode unit 13 that decompresses and decodes the read-out compressed data, a transmission data processing unit 14 that performs preprocessing so that the decoded data conforms to the specifications of the reception processing device, A transmission device unit 15 that performs transmission processing through the HDMI transmission path 30, a transmission control unit 16 that performs authentication control and transmission processing control, a key memory 17 that stores a first device key for a transmission-side device, and the like It is prepared for. The transmission control means 16 is configured using, for example, a microcomputer.

  In this example, the reception processing device 20 is configured as an AV (Audio-Visual) monitoring device. The reception processing device 20 receives the data through the HDMI transmission path 30, and processes the received data. A reception data processing unit 22 that generates display data and sound reproduction data, a monitor device 23 that includes a display 23D and a speaker 23SP, a reception control unit 24 that performs reception processing control, and a second device key for a receiving-side device The key memory 25 for storing the information, the receiving side information memory 26, and the like. The reception control means 24 is configured using, for example, a microcomputer.

  The receiving side information memory 26 includes EDID (Extended Display Identification Data) information as receiving side information. In particular, when the current DVI standard or HDMI standard is used, the reception side information indicates the same as EDID. This EDID information includes information such as resolution information and synchronization frequency information of the display 23D of the AV monitor device as the reception processing device 20, types of signals that can be displayed, pixel clock (pixel clock), horizontal effective period, vertical effective period, and the like. including.

  The HDMI transmission path 30 connecting the transmission processing device 10 and the reception processing device 20 includes a high-speed bus 31 for transmitting video data and audio data, and a low-speed for transmitting EDID data and data for authentication described later. Bus 32.

  FIG. 2 shows a detailed example of the HDMI transmission path 30. As shown in FIG. 2, the transmission device unit 15 includes an HDMI transmission unit 15T, while the reception device unit 21 includes an HDMI reception unit 21R. Between the HDMI transmission unit 15T and the HDMI reception unit 21R, Connected by a high-speed bus 31.

  The high-speed bus 31 is a TMDS serial transmission line that transmits red, green, and blue video data through separate channels (TMDS channel 0, TMDS channel 1, and TMDS channel 2). Separately, a channel for clock transmission synchronized with transmission data is provided for one channel. Therefore, the high-speed bus 31 includes serial transmission paths for four channels as shown in FIG.

  In this case, audio data, control data, and status data are inserted and transmitted in the vertical blanking period and horizontal blanking period of the red, green, and blue image data, respectively. The HDMI transmission unit 15T performs time-division multiplexing of these video data, audio data, control data, and status data in each channel and transmits the data, and also transmits a clock synchronized with the transmission data.

  As shown in FIGS. 1 and 2, the transmission control unit 16 and the reception control unit 24 are connected by a low-speed bus 32.

  In the HDMI standard, plug and play is realized, and the transmission processing device 10 transmits a video signal in accordance with the resolution of the display for display included in the reception processing device 20. The low speed bus 32 is provided in order to realize this plug and play.

The low-speed bus 32 is called a DDC (Display Data Channel), and an I ² C bus that is a bidirectional bus is adopted. The I ² C bus is a low-speed serial bus having a maximum transfer clock frequency of 400 kHz. The transmission control means 16 obtains EDID data as reception side information from the reception processing device 20 via the low-speed bus 32, thereby realizing plug and play.

  That is, when the transmission processing device 10 and the reception processing device 20 are connected via the HDMI transmission path 30, the transmission control means 16 of the transmission processing device 10 receives the reception side information memory 26 of the reception processing device 20 via the low-speed bus 32. To obtain EDID information as receiving side information. Then, the transmission control unit 16 controls the transmission data processing unit 14 in the transmission data transmission process to output video signals having the horizontal scanning frequency and the vertical scanning frequency optimum for the display 23D of the reception processing device 20. This makes it possible to display the video recorded on the DVD 11 on the display 23D in an always optimal state.

  The low speed bus 32 is not used only for plug and play as described above. That is, in this embodiment, the transmission control unit 16 uses the low-speed bus 32 to perform an authentication operation on the reception processing device 20 using the HDCP method. In HDCP, the transmission processing device 10 authenticates that the receiving device is not an unauthorized device, and after the authentication is successful (successful authentication), encrypted transmission of transmission data from the transmission processing device 10 to the reception processing device 20 is not performed. Is possible. Information necessary for this authentication is transmitted via the low-speed bus 32. This authentication operation will be described in detail later.

  The transmission device unit 15 of the transmission processing device 10 is configured by, for example, one LSI (Large Scale Integrated circuit). In this example, the data encryption unit 151 and the encryption control are used for encrypted transmission. Unit 152 and data transmission unit 153. The data transmission unit 153 corresponds to the HDMI transmission unit 15T in FIG.

  The data encryption unit 151 receives video data and audio data from the transmission data processing unit 14, and executes encryption while receiving control from the encryption control unit 152. The encryption control unit 152 controls the encryption of video data and audio data under the control of the transmission control unit 16. In addition, the data transmission unit 153 transmits the data received from the data encryption unit 152 to the reception processing device 20 via the high-speed bus 31 in the HDMI transmission path 30. Here, in this example, HDCP is used as the encryption method in the data encryption unit 151.

  On the other hand, the reception device unit 21 of the reception processing device unit 20 is also composed of, for example, one LSI. In this example, the data reception unit 211, the data decoding unit 212, and the decoding control unit 213 are used. With. The data receiving unit 211 corresponds to the HDMI receiving unit 21R in FIG.

  The data receiving unit 211 receives the encrypted video data and audio data transmitted via the high-speed bus 31 and transfers the video data and audio data to the data decoding unit 212. Next, the encrypted video data and audio data are decrypted by the data decryption unit 212 and restored to the original video signal and audio signal. Thereafter, the restored video signal and audio signal are sent to the reception data processing unit 22.

  Then, the restored video signal and audio signal are subjected to signal processing by the reception data processing unit 22 and then supplied to the monitor device 23, where the video by the video signal is displayed on the display 23D and the speaker 23SP. The audio signal is reproduced as sound. The received data processing unit 22 performs, for example, gradation correction and optimization of signal output to the monitor device 23 according to the horizontal / vertical scanning cycle.

  The first device key of the key memory 17 and the second device key of the key memory 25 are used for authentication of the reception processing device 20 and encryption / decryption of transmission data as will be described later.

  The first device key and the second device key are unique to the transmitting device and the receiving device, respectively, and are encryption keys created from the first device key in a step called “key exchange”. And the decryption key created from the second device key.

  That is, in this example, when the transmission control unit 16 confirms that the reception processing device 20 is not an unauthorized device by an authentication process described later, the transmission control unit 16 reads the first device key in the key memory 17 and performs the encryption control unit 152. To pass. The encryption control unit 152 generates an encryption key using the received first device key and passes it to the data encryption unit 151. The data encryption unit 151 uses this encryption key to execute encryption processing of the video data and audio data from the transmission data processing unit 14, and transfers the encrypted data to the data transmission unit 153. The data transmission unit 153 generates the three-channel serial data as described above and transmits the serial data to the reception processing device 20 through the high-speed bus 31.

  The reception control unit 24 of the reception processing device 20 reads the second device key from the key memory 25 and passes it to the decryption control unit 213 so that the decryption control unit 213 generates a decryption key. The decryption key generated by the decryption control unit 213 is passed to the data decryption unit 212. The data decryption unit 212 decrypts the encrypted video data and audio data received by the data reception unit 211 using the decryption key. Then, the decoded data is supplied to the reception data processing unit 22, and the reproduced video is displayed on the display 23D as described above, and the reproduced sound is emitted from the speaker 23SP.

  The above is the operation when the authentication processing of the reception processing device 20 is performed by the transmission processing device 10 and the authentication is successful and it is determined that the reception processing device 20 is not an unauthorized device.

  On the other hand, in this embodiment, when the authentication processing of the reception processing device 20 is performed by the transmission processing device 10 and the authentication that the reception processing device 20 is not an unauthorized device fails, Not performed.

  In this embodiment, when this authentication failure occurs, the transmission processing device 10 does not perform transmission by encrypting video data or audio data, but instead is information for notifying the user of the authentication failure. The message information that can be reproduced and output by the reception processing device 20 is transmitted to the reception processing device 20 without being encrypted.

  For example, the example shown in FIG. 3 or FIG. 4 is an example of a message screen that is displayed on the display screen 23D to notify the user of the authentication failure. The example of FIG. 3 is a message screen for notifying that video and audio cannot be displayed or reproduced because authentication of a receiving device connected to the HDMI transmission path has failed.

  In addition, the example of FIG. 4 has a content that prompts the user to switch to a connection interface when there is another connection interface other than HDMI because authentication of a receiving device connected to the HDMI transmission path has failed. It is a message screen.

  In this embodiment, the transmission processing apparatus 10 reads and acquires the video data of the message screen as shown in FIG. 3 or FIG. 4, for example, which is recorded in advance on the DVD 11, and the read video data of the message screen. Are not encrypted and transmitted to the reception processing apparatus 20 through the high-speed bus 31 as raw data.

  Information indicating that the transmission data is encrypted is inserted and added to the transmission data that is encrypted and transmitted. The receiving device unit 21 extracts information indicating that this is encrypted from the received transmission data, recognizes that the received transmission data is encrypted, and performs the decryption process as described above. Do.

  Similarly, information indicating that the video data is not encrypted is inserted and added to the video data of the message screen transmitted as raw data without being encrypted. Then, when receiving the message screen data, the receiving device unit 21 extracts information indicating that the message is not encrypted, recognizes the information, and decrypts the encryption in the data decryption unit 212. The image data of the message screen is supplied to the reception data processing unit 22 by passing the conversion process. As a result, a message screen for notifying the user of the authentication failure as shown in FIG. 3 or 4 is displayed on the display 23D of the monitor device 23.

  Of course, the voice message data of the authentication failure may be transmitted together with the video data of the message screen of the authentication failure as shown in FIGS. In that case, an authentication failure voice message is emitted by the speaker 23SP together with the message screen of the display 23D, so that the user immediately recognizes the authentication failure and takes appropriate measures such as switching to another interface. It can be done quickly.

  Further, the video data of the message screen and the voice message data are not recorded on a recording medium such as a DVD, but are stored in a memory included in the transmission processing apparatus 10 and read out for use. Also good.

  Further, the transmission processing device 10 is provided with an OSD (On Screen Display) generation circuit and an OSD synthesis circuit, and these OSD generation circuit and OSD synthesis circuit are used to display a message in OSD on copyright-free data. There may be. In HDMI, since PCM audio support is a mandatory standard for reception processing devices, it is also effective to notify the user that authentication has failed by voice.

[Authentication operation and processing operation according to the authentication result]
Next, the details of the authentication operation in the transmission processing apparatus described above and the processing operation in the transmission processing apparatus according to the authentication result will be further described. That is, FIG. 5 and FIG. 6 that is a continuation thereof are flowcharts for explaining an example of the authentication operation in the transmission processing apparatus and the processing operation according to the authentication result. Each step of the flowcharts shown in FIGS. 5 and 6 is mainly executed by the transmission control unit 16 of the transmission processing device 10 while controlling the transmission device unit 15.

  First, when the HDMI cable is connected to the transmission processing device 10 and the reception processing device 20, the transmission control unit 16 of the transmission processing device 10 acquires information on the connection state between the transmission processing device 10 and the reception processing device 20. (Step S1). This is because the HDMI cable has a signal line called HPD (Hot Plug Detected) controlled by the receiving device, and the transmission control means 16 monitors this HPD, so that the receiving device is connected by HDMI. It uses a mechanism that understands.

  Then, based on the acquisition of the connection state information through the HPD in step S1, the transmission control unit 16 determines whether or not the receiving device is connected by HDMI (step S2). If it is determined that there is no connection, the process returns to step S1 to continue monitoring the connection state.

  When it is determined in step S2 that the connection state is established, the transmission control unit 16 acquires the reception side information stored in the reception side information memory 26 through the low-speed bus 32, in this example, EDID, and binary. By analyzing the EDID, which is data, information such as the horizontal synchronization frequency, the vertical synchronization frequency, and the video resolution that can be displayed on the display 23D of the monitor device 23 of the reception processing device 20 is recognized (step S3).

  In this way, when the specification of the reception processing device 20 is known in the HDMI connection state, the transmission control unit 16 then proceeds to an HDCP authentication step.

  First, the transmission control part 16 performs 1st authentication (step S4). This first authentication is performed as follows.

  That is, the transmission control unit 16 acquires the first device key on the transmission device side from the key memory 17, passes the acquired first device key to the encryption control unit 152, and controls reception through the low-speed bus 32. Pass to part 24.

  On the other hand, the reception control unit 24 of the reception processing device 20 acquires the second device key on the receiving device side from the key memory 25, passes it to the decryption control unit 213, and passes it to the transmission control unit 16 through the low-speed bus 32. .

  The transmission control unit 16 passes the second device key received through the low-speed bus 32 to the encryption control unit 152, and the reception control unit 24 receives the first device key received through the low-speed bus 32. The data is transferred to the decryption control unit 213.

  Upon receiving the control instruction from the transmission control unit 16, the encryption control unit 152 generates the first device key, the second device key, and the encryption control unit 152 received from the transmission control unit 16. A predetermined calculation is performed based on the random number An to be transmitted, and the calculation result R0 is passed to the transmission control unit 16. The transmission control unit 16 stores the calculation result R0.

  Also, upon receiving a control instruction from the reception control unit 24, the decryption control unit 213 generates the first device key, the second device key, and the decryption control unit 213 received from the reception control unit 24. A predetermined calculation is performed based on the random number An ′ to be transmitted, and the calculation result R0 ′ is sent to the transmission control unit 16 through the reception control unit 24 and the low-speed bus 32.

  The transmission control unit 16 compares the stored calculation result R0 with the calculation result R0 ′ received through the low-speed bus 32. If the two match, the transmission control unit 16 determines that the first authentication is successful, and matches. Otherwise, it can be determined that the first authentication has failed. This completes the first authentication process.

  Then, the transmission control unit 16 determines whether or not the first authentication is successful (step S5). When it is determined that the first authentication is successful, the receiving device connected to the transmission control unit 16 It is determined whether or not it is a (relay device) (step S6), and when it is determined that it is a repeater, the transmission control unit 16 executes the second authentication (step S7). If it is determined in step S6 that the repeater is not a repeater, the transmission control unit 16 performs the third authentication while confirming the connection state, as will be described later, without performing the second authentication.

  Here, the repeater will be described with reference to FIG. A reception processing device according to the HDMI standard has a video playback function and / or an audio playback function such as a display and a speaker. However, the transmission processing apparatus may be connected to a relay device such as an AV amplifier that does not have a display or a speaker. In this case, the relay device receives the video data and audio data from the transmission processing device, performs predetermined processing, and then transmits the video data and audio data to the reception processing device having a display, a speaker, and the like.

  In such a case, the transmission processing apparatus needs to authenticate with the reception processing apparatus via the relay apparatus. The second authentication is authentication in such a case.

  In the example of FIG. 7, a DVD player 41 as an example of a transmission processing device and an AV amplifier 42 as an example of a repeater are connected by an HDMI cable 51, and a monitor as an example of the AV amplifier 42 and a reception processing device. A state is shown in which the device 43 is connected by an HDMI cable 52.

  In the example of FIG. 7, when playback is performed by the DVD player 41, the playback video data and audio data are amplified by an AV amplifier 42 that is a repeater (relay device) and then supplied to the monitor device 43. An image is displayed on the display screen, and the sound is reproduced by sound through the speaker.

  When the transmission control unit 16 determines in step S6 that the device connected to the transmission processing apparatus 10 via the HDMI cable is a repeater, it starts second authentication in step S7. First, an authentication key (corresponding to the second device key stored in the key memory 26 of the reception processing apparatus) connected to the device that is a repeater via an HDMI cable and an authentication key of the repeater are predetermined. The KSV (KEY Selection Vector) list merged by the method is acquired through the repeater device.

  Then, the transmission control unit 16 passes the acquired KSV list to the encryption control unit 152. The encryption control unit 152 performs a predetermined calculation based on the KSV list and passes the calculation result V to the transmission control unit 16. The transmission control unit 16 stores the calculation result V.

  In this case, the decryption control unit 213 of the reception processing device connected to the repeater performs a predetermined calculation based on the authentication key of the repeater and the authentication key of the reception processing device, and the calculation result V ′ Is sent from the reception processing device through the repeater, and is acquired and compared with the stored calculation result V. If both match, it is determined that the second authentication is successful, If they do not match, it can be determined that the second authentication has failed. This completes the second authentication process.

  Then, the transmission control unit 16 determines whether or not the second authentication is successful (step S11 in FIG. 6). When the transmission control unit 16 determines that the second authentication is successful, the transmission control unit 16 again monitors the HPD state to monitor the HDMI. Information on the connection state is acquired (step S12). When it is determined in step S6 that the device connected to the transmission control apparatus 10 is not a repeater and the second authentication is not necessary, the transmission control unit 16 jumps from step S6 to step S12.

  Then, in step S12, the transmission control unit 16 determines whether or not the connection state of the device based on HDMI is maintained (step S13). When it is determined that the connection state is maintained, the third authentication is performed. (Step S14).

  In the third authentication process, the transmission processing device 10 and the reception processing device 20 (when there are repeater devices, the transmission processing device 10 and the repeater device) perform a predetermined calculation and obtain an encrypted session key. And whether or not they are the same value is periodically monitored, for example, every 128 frames of the video frame. Specifically, the transmission control unit 16 acquires the result of the predetermined calculation from the reception control unit 24 of the reception processing device 20, and the acquired calculation result and the predetermined calculation in the encryption control unit 152. The third authentication process is performed by comparing the result and determining that the third authentication is successful if the two match, and determining that the third authentication has failed if they do not match.

  Next, the transmission control unit 16 confirms whether or not the authentication is successful in the third authentication (step S15), and when determining that the third authentication is successful, the transmission control unit 16 determines that the authentication is successful. The data encryption unit 151 encrypts the video data and the audio data, and transmits the encrypted data from the data transmission unit 153 (step S16). At this time, the transmission control unit 16 controls the transmission data processing unit 14 so that the video data to be transmitted is a video signal having a horizontal scanning frequency and a vertical scanning frequency that are optimal for the display 23D of the monitor device 23 of the reception processing device 20. Output in the state.

  After step S16, the process returns to step S12, and the third authentication described above is repeated every 128 frames while it is determined that the connection state is maintained based on the monitoring result of the HPD state.

  When it is determined in step S13 that the HDMI connection has been disconnected based on the monitoring result of the HPD state, the transmission control unit 16 returns from step S13 to step S1, and then when the HDMI connection is performed, The above processing is performed.

  As described above, after the HDMI cable is connected between the transmission processing device 10 and the reception processing device 20, the authentication is performed, and the data is output in an optimal form by the plug and play function based on the successful authentication. It is the flow of.

  Next, processing when one of the first authentication, the second authentication, and the third authentication has failed will be described.

  That is, when it is determined that the first authentication has failed in step S5, or when it is determined that the second authentication has failed in step S11, or when it is determined that the third authentication has failed in step S15, the digital content Therefore, the transmission control unit 16 does not transmit effective transmission data as described above.

  Instead, in this embodiment, the transmission control unit 16 reads the video message data and / or audio message data stored in advance on the DVD 11 by controlling the reading unit 12 (step S17). At this time, the transmission control unit 16 turns off the encryption function of the data encryption unit 151 to output the read video message data and / or voice message data as raw data without encryption. . As described above, the data transmitted at this time includes information indicating that the data is not encrypted (step S18). This processing routine ends.

  As described above, when the reception device unit 21 of the reception processing device 20 receives the message data of the raw data, the reception device unit 21 detects information indicating the raw data included therein, and performs data decoding based on the information. The decoding in the conversion unit 212 is turned off, and the received data processing unit 22 is passed. Accordingly, the message data from the reception data processing unit 22 is supplied to the monitor device 23, and the fact that the HDCP authentication in HDMI has failed is displayed to the user by displaying a message on the screen and / or by emitting a voice message. Informed.

  As described above, according to this embodiment, when authentication fails, it is possible to prevent user confusion by transmitting raw message data that is not encrypted.

  For example, if message data indicating that authentication is not successful is output as a reason that a valid video / audio is not output, as shown in FIG. The wrong problem is solved.

  If the reception processing device 20 has another connection interface of the HDMI interface, it is also effective to issue a message instructing to switch to the other input interface as shown in FIG. It is. If the user receives this message and switches the connection interface as instructed, valid video data can be viewed.

  This is because the reception processing device 20 is not a malicious device that duplicates copyrighted material, but the HDMI authentication process has failed for some reason, or is often provided by a single LSI. 15 or the receiving device unit 21 is only broken down, it is effective because it is possible to see the valid data safely by transmitting the data using another connection interface. is there.

  In particular, in recent years, there are many reception processing apparatuses equipped with HDMI, and they are often provided with a plurality of terminals such as components. Therefore, the above method is effective.

  In addition, when the HDCP authentication fails, if the authentication retry is repeated or the transmission of video data and audio data is stopped as in the past, the reception processing device 20 remains unresponsive for a long time. The state is maintained. In the HDMI connection, when images and sound are not normally output, the user usually tries to connect / disconnect the HDMI cable. However, when the HDMI cable is connected or disconnected, EDID data (usually 256 bytes) is acquired via the low-speed bus 32 of 400 kbps at the fastest, which takes time, and the above-described authentication process is performed again. If the authentication fails, the cable must be connected and disconnected again, which is a painful operation for the user.

  On the other hand, according to the above-described embodiment, the user is surely notified of the authentication failure by the message data, so that the user can grasp the state of the HDMI connection and flexibly cope with it. It is possible.

  Also in the reception processing device 20, it is not necessary to perform a special calculation for executing the authentication processing function as in the case of Patent Document 3 or a switching process. The reception processing device 20 only needs to receive and display the raw data of the authentication failure message data, and reproduce and output the sound, and there is no need to change hardware or software. can get.

  In particular, in the HDMI standard, the resolution and audio format that should be supported at the minimum are defined as the mandatory standards, and therefore, the display and speaker for display should be provided at the minimum in the reception processing device 20. Therefore, according to this embodiment, since the notification by the message data can be realized using the user interface that is provided in the reception processing device 20 as standard, there is also an advantage that the cost is not increased.

  Further, since it is possible to inform the user of the authentication failure using a user interface such as a display for display or a speaker that seems to be standard on the data receiving side, the transmission processing device 10 side thereof There is no need to provide a user interface. A DVD deck or the like does not always have a display panel. In such a case, it can be said that the cost is reduced.

  Further, since the invention of the above-described embodiment is not of the nature of interpreting something on the receiver side and authenticating the user without depending on the hardware specification or software specification on the receiver side. The failure can be communicated and the user can respond flexibly.

  Note that the message data transmitted as raw data may be composed of both video data and audio data, or may be only video data or only audio data.

  The above-described embodiment is an example in which a transmission processing device and a reception processing device are connected using a connection interface based on the HDMI standard. However, as described above, the present invention is a connection interface based on the HDMI standard. It is not limited. For example, it is needless to say that the present invention can also be applied to the case where the HDCP technology for DVI transmission described above is used and the case of the IEEE 1394-DTCP method.

  Further, in the above-described embodiment, the case of the connection interface that performs the authentication process on the transmission processing device side and encrypts the transmission data when the authentication is successful has been described. However, the transmission data is encrypted. Instead, the present invention can also be applied to a case where transmission data is transmitted to the receiving apparatus by performing a predetermined scramble process with the receiving apparatus.

It is a block diagram which shows the transmission / reception system containing embodiment of the transmission processing apparatus by this invention. It is a figure for demonstrating the connection interface used with the transmission processing apparatus of embodiment. It is a figure which shows an example of the message of the authentication failure sent from the transmission processing apparatus of embodiment. It is a figure which shows the other example of the message of the authentication failure sent from the transmission processing apparatus of embodiment. It is a figure which shows a part of flowchart for demonstrating the authentication process in the transmission processing apparatus of embodiment, and the processing operation according to the authentication result. It is a figure which shows a part of flowchart for demonstrating the authentication process in the transmission processing apparatus of embodiment, and the processing operation according to the authentication result. It is a figure used for description of the authentication process in the transmission processing apparatus of embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Transmission processing apparatus, 15 ... Transmission apparatus part, 16 ... Transmission control part, 30 ... HDMI transmission path (HDMI cable), 151 ... Data encryption part, 152 ... Encryption control part, 20 ... Reception processing apparatus

Claims (4)

Prior to transmission of transmission data, when the authentication process is successful for the connected receiving device, and when the authentication is successful, the transmission processing device transmits transmission data that can be correctly reproduced by the receiving device to the receiving device,
When authentication for the receiving device fails, message information that can be reproduced and output by the receiving device for notifying the user that the authentication has failed is transmitted to the receiving device. apparatus. The transmission processing apparatus according to claim 1,
When the authentication for the receiving device is successful, the transmission data is encrypted and transmitted to the receiving device,
The transmission processing device, wherein when the authentication of the receiving device fails, the message information is transmitted to the receiving device without performing an encryption process. In the transmission processing device according to claim 1 or 2,
The transmission processing apparatus, wherein the message information is a message prompting to use another input / output interface that can be used with the receiving apparatus. Prior to transmission of transmission data, when performing authentication processing on the receiving device, when the authentication is successful, a transmission processing method for transmitting transmission data that can be correctly reproduced by the receiving device to the receiving device,
When authentication for the receiving device fails, message information that can be reproduced and output by the receiving device for notifying the user that the authentication has failed is transmitted to the receiving device. Method.

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