JP4078573B2 - Digital signal transmission apparatus, digital signal transmission method, and digital signal recording medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a digital signal transmission apparatus, a digital signal transmission method, and a digital signal recording medium, and can be applied, for example, when video data transmitted by digital satellite broadcasting is recorded on an optical disk. The present invention defines the first generation information so as to extend the second generation information indicating the copy generation of the unencrypted digital signal, and, if necessary, the generation information. By converting, when the encryption mode is switched according to the copy generation of the digital signal, the copy generation of the digital signal can be easily managed.
[0002]
[Prior art]
Conventionally, in a video signal, illegal copying is restricted by CGMS (Copy Generation Management System).
[0003]
In other words, CGMS is a system that transmits information indicating the copy generation of a video signal (hereinafter referred to as CGMS information) together with the video signal and restricts copying based on this CGMS information. CGMS includes CGMS-A for transmitting CGMS information in a vertical blanking period of a video signal for a video signal based on an analog signal, and CGMS-D for a video signal based on a digital signal.
[0004]
In these CGMS-A and CGMS-D, as shown in FIG. 7, three copy generations are defined by 2-bit CGMS information, and the generation of the video signal generation is not restricted at all (Free Free). ), A generation in which only one generation is permitted (Copy Once) or a generation in which copying is not permitted (No Copy) is indicated.
[0005]
Of these, the generation (Free) for which copying is not restricted is set to a private video signal obtained from, for example, a digital video camera, and the generation (Copy Once) for which only one generation is permitted is, for example, a reproduction-only optical disc. Etc., and the video signal is set such that the copyright holder allows the copy only for private reproduction. The copy that is not allowed to be copied (No Copy) is a video signal obtained from a copy from a generation that is allowed to be copied for only one generation (Copy Once), or a video signal obtained from a reproduction-only optical disc, etc. Is set to a video signal or the like that prohibits private copying.
[0006]
Such CGMS information is transmitted, for example, assigned to a header of an MPEG (Moving Picture Experts Group) which is an industry standard.
[0007]
As a result, in the recording apparatus for recording the video signal transmitted in this manner, the recording of the generation (No Copy) video signal in which copying is not permitted is stopped according to the CGMS information. In addition, for a generation in which only one generation is allowed to be copied (Copy Once), a video signal is recorded on a desired recording medium, and at this time, the CGMS information is updated to describe that the generation is not allowed to be copied thereafter (No Copy). . On the other hand, for generations (Free) in which copying is not restricted at all, video signals that are sequentially input are recorded without updating the CGMS information.
[0008]
[Problems to be solved by the invention]
By the way, in the transmission of such a digital video signal, it is considered to transmit it in an encrypted form. Further, at this time, in order to reflect the intention of the copyright holder in the security by the encryption, the copy generation in the digital video signal is considered. Switching the encryption mode accordingly is under study.
[0009]
In this case, it is considered that strong encryption is applied to a digital video signal for which the copyright holder prohibits private copying. In addition, it is considered that more lenient encryption is applied to digital video signals that the copyright holder allows only private copying. Furthermore, it is considered that the digital video signal copy that allows only such private duplication is only required to be moderately encrypted, and if the copy is not restricted at all, it is considered that there is no need for encryption.
[0010]
Therefore, in this case, by setting the encryption mode according to the conventional CGMS information, it is considered that this kind of encryption mode can be easily set reflecting the intention of the copyright holder.
[0011]
However, in the CGMS information, the generation in which copying is not permitted (No Copy) is a generation in which copying is not permitted from the beginning (No Copy), or a copy of a generation in which copying is permitted only for one generation (Copy Once). In the end, it is difficult to determine whether it is a thing, and after all, the encryption mode can be switched only in three stages including the case where no encryption is performed.
[0012]
In this case, since there is one undefined code “0, 1” in the CGMS information, re-definition of the CGMS information using this undefined code makes it possible to simplify the encryption mode according to the CGMS information. It can be set. However, if this is done, there is a problem that compatibility with conventional devices using CGMS information cannot be maintained.
[0013]
On the other hand, a method of setting information indicating the copy generation so as to cope with such four-stage encryption is also conceivable. In this case, it is necessary to manage two types of generation information. There is a problem that the processing becomes complicated accordingly.
[0014]
The present invention has been made in consideration of the above points. When the encryption mode is switched according to the copy generation of the digital signal, the digital signal can easily manage the copy generation of the digital signal. The present invention intends to propose a digital signal transmission apparatus, a digital signal transmission method, and a digital signal recording medium.
[0015]
[Means for Solving the Problems]
To solve this problem Claim 1 or Claim 2 In the invention, the digital signal and the first generation information are encrypted by an encryption mode corresponding to the first generation information added to the digital signal, applied to the digital signal transmission apparatus or the digital signal transmission method. To generate an encrypted digital signal, and send encrypted information indicating an encryption mode and an encrypted digital signal, wherein the first generation information is information indicating a copy generation of the digital signal, Indicates the copy generation of an unencrypted digital signal Instead of second generation information , Extending the second generation information Information to be set, the second generation information Generations for which copying is prohibited, and generations for which copying is prohibited, and generations classified as generations for which copying provided for the second generation information is prohibited are provided. This information is classified into the generations that are prohibited from being copied from the beginning and the generations that are prohibited from being copied by the generations that are prohibited from being copied. Like that.
[0016]
Also Claim 3 or Claim 4 Applied to a digital signal transmission apparatus or digital signal transmission method, reproduces an encrypted digital signal from a recording medium, releases the encryption of the encrypted digital signal, and releases the encrypted digital signal. The first generation information added to the signal is converted into second generation information. At this time The first generation information is information indicating the copy generation of the digital signal, and is set by extending the second generation information instead of the second generation information indicating the copy generation of the unencrypted digital signal. The generation provided in the second generation information and the generation in which the subsequent copy is prohibited are provided, and the copy provided in the second generation information is classified into the generation prohibited. Information to be classified into a generation in which copying is prohibited from the beginning by the generation in which copying is prohibited and a generation in which copying is prohibited by copying in a generation in which subsequent copying is prohibited Is Like that.
[0017]
Also In the invention of claim 5, When applied to a digital signal recording medium, the digital signal is encrypted by an encryption mode corresponding to the added first generation information, recorded together with encryption information indicating the encryption mode, and the first Generation information Information indicating a copy generation of a digital signal, information set by extending the second generation information instead of second generation information indicating a copy generation of an unencrypted digital signal, The generation provided in the second generation information and the generation in which the subsequent copy is prohibited are provided, and the generation classified into the generation in which the copy provided in the second generation information is prohibited is the copy. This information is classified into the generations that are prohibited from copying from the beginning due to the generations that are prohibited, and the generations that are prohibited from being copied by the generations that are prohibited from copying thereafter. Like that.
[0018]
According to the configuration of claim 1 or claim 2, In accordance with the encryption mode corresponding to the first generation information added to the digital signal, the digital signal and the first generation information are encrypted and an encrypted digital signal is generated and transmitted together with the encrypted information. 1 generation information is information indicating the copy generation of the digital signal, Instead of the second generation information indicating the copy generation of the unencrypted digital signal, the information is set by extending the second generation information, and the generation provided in the second generation information The generations that are prohibited from being copied are prohibited, and the generations classified into the generations in which the copy provided in the second generation information is prohibited are prohibited from being copied from the beginning by the generation in which the copy is prohibited. Information that is classified into a generation that is prohibited from being copied by a generation that is prohibited from copying after that By doing so, it is possible to manage the copy generation by centrally managing the second generation information and the first generation information from the past, and to achieve compatibility with conventional devices.
[0019]
Also According to the configuration of claim 3 or claim 4, When reproducing the encrypted digital signal from the recording medium, the encryption is released according to the encryption information indicating the encryption mode, and the added first generation information is converted to the second generation information. The second generation information is information indicating the copy generation of the unencrypted digital signal, and the first generation information is information indicating the copy generation of the digital signal, A generation provided in the second generation information and a generation in which subsequent copying is prohibited, and a generation classified as a generation in which copying provided in the second generation information is prohibited, This information is divided into the generations where copying is prohibited from the beginning due to the generations where copying is prohibited and the generations where copying is prohibited due to copying by the generations where copying is prohibited thereafter. In this way, similarly, the second generation information from the past and the first generation information can be managed centrally to manage the copy generation, and compatibility with the conventional device can be achieved. . Further, the copy generation can be managed by updating the first and second generation information as necessary.
[0020]
Also With the configuration of claim 5, When applied to a digital signal recording medium, the digital signal is encrypted with an encryption mode corresponding to the added first generation information, and the digital signal is recorded together with the encryption information indicating the encryption mode. Generation information A generation provided in the second generation information and a generation in which subsequent copying is prohibited, and a generation classified as a generation in which copying provided in the second generation information is prohibited, This information is divided into the generations where copying is prohibited from the beginning due to the generations where copying is prohibited and the generations where copying is prohibited due to copying by the generations where copying is prohibited thereafter. In this way, similarly, the second generation information from the past and the first generation information can be managed centrally to manage the copy generation, and compatibility with the conventional device can be achieved. . Further, the copy generation can be managed by updating the first and second generation information as necessary.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings as appropriate.
[0022]
(1) Configuration of the embodiment
FIG. 2 is a block diagram showing the satellite broadcasting system according to the embodiment of the present invention. In the satellite broadcasting system 1, various digital broadcasts are uplinked to the satellite 3 from the broadcasting station 2, and the digital broadcast downlinked from the satellite 3 is received in each home 4.
[0023]
Here, in the broadcasting station 2, transport streams TP1 to TPN based on digital video signals and digital audio signals are time-division multiplexed by a multiplexer (MUX) 5 and then modulated by a modulator (MOD) 6. Further, the modulation signal obtained from the modulator 6 is frequency-multiplexed with other modulation signals generated in the same manner, and uplinked from the antenna 8.
[0024]
At this time, the broadcasting station 2 converts the digital video signal and the digital audio signal supplied from the server or the like into the transport streams TP1 to TPN according to the MPEG format, and the multiplexing apparatus 5 performs time division on the transport streams TP1 to TPN. Multiplex. In this embodiment, the conventional CGMS information (CGMS-D) is added to the digital video signal thus converted into the transport streams TP1 to TPN.
[0025]
On the other hand, the CGMS information in the transport streams TP1 to TPN is defined by extending the conventional CGMS information (CGMS-D) as shown in FIG. 3 as a copy protection descriptor among various descriptors. . That is, the CGMS information is copy control information (DRCD: defined as the same as the conventional CGMS information (CGMS-D) as described above with reference to FIG. 7 when the 2-bit copy control type is “0, 1”. Digital Recoding Control Data) is assigned. The copy control type is a field indicating whether or not encryption is performed with 2 bits. When the logic is “0, 1”, the encryption process of the transport stream is instructed. When the logic is “1, 1”, the encryption is performed. Instructs not to process.
[0026]
Furthermore, in this embodiment, when the copy control type is “0, 1”, extended CGMS information (M-CGMS) is defined. Here, the expanded CGMS information (M-CGMS) corresponds to the conventional CGMS information (CGMS-D), the generation (Free) in which copying is not restricted (logical “0, 0”), and only one generation. A generation that can be copied (Copy Once) (logical “1, 0”) and a generation that cannot copy (Never Copy) (logical “1, 1”) are defined.
[0027]
In addition to this, the expanded CGMS information (M-CGMS) is a copy-prohibited generation (No More Copy) to a logical “0, 1” that is not defined in the conventional CGMS information (CGMS-D). ) Is defined. As a result, in this embodiment, a copy-prohibited one (1, 1) is distinguished from a copy-prohibited one (1, 0) that has been copied once and is copy-prohibited. It has been made so that it can. In order to make it possible to listen to a program by so-called time shift, CGMS information (M-CGMS) in digital satellite broadcasting is generally set to a generation other than a generation (Never Copy) (logical “1, 1”) that is not allowed to be copied. Is done.
[0028]
In the copy protection descriptor, an analog copy protection field is formed following the copy control type field. Here, the analog copy protection regulates the output of the video signal based on the analog signal, and the copy is restricted in four stages including the case where the copy is possible without restricting the copy.
[0029]
In other words, analog copy protection is specified to output a video signal without executing any copy guard processing when a code “0, 0” that can be copied is set, whereas it is a type 1 copy. When the code “0, 1” indicating the guard is set, it is defined that the pseudo synchronization signal and the AGC pulse are inserted into the video signal and output. In addition, when the code “1, 0” indicating the type 2 copy guard is set, in addition to the type 1 processing, two continuous lines are inverted, and a divided burst is inserted to output a video signal. When the code “1, 1” indicating the type 3 copy guard is set, in addition to the type 1 process, four continuous lines are inverted, and a divided burst is inserted to output a video signal. It is prescribed.
[0030]
In this embodiment, the copy control type is set when converting a digital video signal and a digital audio signal into a transport stream so as to correspond to the conventional CGMS information (CGMS-D). Corresponds to CGMS information (CGMS-A) indicating the copy generation of the video signal by an analog signal.
[0031]
Thus, when the broadcast station 2 generates the transport streams TP1 to TPN, the conventional CGMS information (CGMS-D) added to the digital video signal is expanded by the format shown in FIG. 3 (M-CGMS information). ). Further, the broadcast station 2 uses the scrambler 9 for the encryption program adopted by the broadcast station 2 for the conditional access (CA) program among the transport streams transmitted by time division multiplexing in this way. The data is encrypted using the encryption method.
[0032]
Therefore, when converting the conventional CGMS information (CGMS-D) into the extended CGMS information (M-CGMS) in this way, the conventional CGMS information (CGMS-D) for managing the copy generation in three stages is converted. By converting the copy generation into expanded CGMS information (M-CGMS) that is managed in four stages, a code indicating three copy generations based on the CGMS information (CGMS-D) is a copy generation based on the CGMS information (M-CGMS). The broadcast station 2 simply updates the copy control type field and converts the CGMS information. In this embodiment, the CGMS information and the content are surrounded by hatching to indicate that they are encrypted.
[0033]
Thus, in such digital satellite broadcast encryption, the setting is made from the viewpoint of whether or not to allow a trial listening by charging, regardless of the copyright of the content. As a result, the broadcast station 2 encrypts and transmits the CGMS information and content by the broadcast station's own encryption, and transmits the key data and the like for canceling the encryption separately by a packet or the like.
[0034]
The home 4 receives a broadcast wave that is downlinked from the satellite 3 via the antenna 10 and processes the received wave by an IRD (Integrated Receiver Decoder) 11 to receive a desired broadcast wave. Further, the home 4 outputs a digital video signal DV and an analog signal video signal AV to various devices for the received broadcast wave program. In the home 4, the received program is recorded and reproduced by the optical disc apparatus 12, which is a bit stream recorder, via the IEEE 1394 bus BUS.
[0035]
FIG. 1 is a block diagram showing the IRD 11 and the optical disc apparatus 12. In the IRD 11, the channel selection circuit 21 receives a broadcast wave from the antenna 10 via a down converter (not shown), and receives a desired broadcast channel from the broadcast wave. Further, the channel selection circuit 21 selectively takes in a desired bucket from the received broadcast channel and expands the time axis to output a transport stream TP of the program selected by the user.
[0036]
When the transport stream TP output from the channel selection circuit 21 has been encrypted, the descrambler 22 cancels the encryption and outputs it.
[0037]
A decoder (DEC) 23 processes the transport stream TP output from the descrambler 22 to generate a digital video signal and a digital audio signal. In addition, the decoder 23 replaces the transport stream TP output from the descrambler 22 with the transport stream TP output from the descrambler 24 when the user selects to listen to the optical disk device 12 instead of the digital satellite broadcast. Then, the digital video signal and the digital audio signal reproduced by the optical disk device 12 are output.
[0038]
At this time, the decoder 23 converts the extended CGMS information (M-CGMS) added to the transport stream into the conventional CGMS information (CGMS-D) according to the conversion rule shown in FIG. 6, and adds it to the digital video signal. Output.
[0039]
In this way, the transport stream TP output from the descrambler 22 is simply transmitted through a digital satellite broadcast transmission path, and the CGMS information (M -CGMS) is generated by converting conventional CGMS information (CGMS-D) added to a digital video signal into corresponding expanded CGMS information (M-CGMS). Thus, in this embodiment, when processing the transport stream TP output from the descrambler 22, the decoder 23 simply holds the code of the expanded CGMS information (M-CGMS) as it is. CGMS information (M-CGMS) expanded by converting the format is converted into conventional CGMS information (CGMS-D).
[0040]
On the other hand, in this embodiment, the transport stream reproduced by the optical disc apparatus 12 from the descrambler 24 is input to the decoder 23. In this case, the transport stream input to the decoder 23 is used. In the stream, a copy generation of only one generation proceeds, and a subsequent copy-prohibited generation (No More Copy) occurs. In this case, in the CGMS information (M-CGMS) added to the transport stream TP, there is a code based on logic “0, 1” which is not defined in the conventional CGMS information (CGMS-D).
[0041]
In the decoder 23, when the expanded CGMS information (M-CGMS) is logical “0, 1”, the code based on the logical “0, 1” is copied in the conventional CGMS information (CGMS-D). After conversion to a code with logic “1, 1” indicating an unacceptable generation (No Copy), format conversion is performed to convert the code into conventional CGMS information (CGMS-D). In this way, when the decoder 23 inputs the transport stream TP from the descrambler 24, the decoder 23 detects the encryption information (EMI) detected by the descrambler 24 and the CGMS information (M-CGMS) added to the transport stream TP. ). Furthermore, when the copy generation based on the encryption information (EMI) is ahead of the CGMS information (M-CGMS), the decoder 23 determines that the copy generation based on the encryption information (EMI) is CGMS information (M-CGMS). Update.
[0042]
Here, the encryption information (EMI) is information for specifying an encryption mode in IEEE 1394, and specifies the encryption mode in association with the extended CGMS information (M-CGMS) as shown in FIG. It is made like that. That is, the encryption information (EMI) specifies that encryption is not performed when the logic is “0, 0”, and encryption according to mode C having the lowest level is specified when the logic is “0, 1”. Further, the encryption information (EMI) specifies encryption in mode B, which is the next higher level of mode C when the logic is “1, 0”, and the highest level when the logic is “1, 1”. Specifies encryption in mode A.
[0043]
As a result, the decoder 23 updates the copy information constituting means for updating the copy generation based on the CGMS information (M-CGMS).
[0044]
The digital / analog conversion circuit (D / A) 25 performs digital / analog conversion processing on the digital video signal and digital audio signal output from the decoder 23, and outputs the video signal and audio signal based on the analog signal to an external device. In these processes, the digital / analog conversion circuit (D / A) 25 converts the CGMS information (CGMS-D) added to the digital video signal into CGMS information (CGMS-A) corresponding to the video signal based on the analog signal. Then, it is added to the video signal and output.
[0045]
The copy guard circuit 26 performs a copy protection process on the video signal in accordance with the CGMS information (CGMS-A) of this video signal and the analog copy protection described above with reference to FIG. 3, and outputs this video signal to an external device.
[0046]
The interface (I / F) 28 outputs the digital video signal and digital audio signal output from the decoder 23 to an external device in a predetermined format.
[0047]
The scrambler 30 encrypts and outputs the transport stream TP output from the descrambler 22. At this time, the scrambler 30 sets encryption information (EMI) indicating an encryption mode in accordance with the CGMS information (M-CGMS) added to the transport stream TP, and transcodes according to the encryption information (EMI). Encrypt the port stream TP.
[0048]
The scrambler 30 forms a packet from the transport stream encrypted in this way, adds the encryption information (EMI) to the subcode of this packet, and outputs it.
[0049]
The interface (I / F) 31 constitutes an input / output circuit of the IEEE1394 bus BUS, outputs the output data of the scrambler 30 to an external device, and also specifies the IRD 11 from the external device and inputs the data input by the descrambler 24. Output to. As a result, the IRD 11 is connected to an external device through the IEEE 1394 bus BUS so that reception results and the like can be input and output.
[0050]
Contrary to the scrambler 30, the descrambler 24 decrypts and outputs the input data input from the interface 31 according to the encryption information (EMI) added to the input data. Further, the descrambler 24 outputs this encryption information (EMI) to the decoder 23.
[0051]
In the optical disc apparatus 12, an interface (I / F) 40 is connected to the IRD 11 and other external devices via the IEEE 1394 bus BUS, and inputs / outputs various data to / from these devices. In these processes, the interface (I / F) 40 inputs a packet based on the transport stream output from the IRD 11 via the IEEE 1394 bus BUS and outputs the packet to the descrambler 41. The output data of the scrambler 42 is output to the IRD 11.
[0052]
The descrambler 41 receives the output data of the interface 40, acquires the encryption information (EMI) from the subcode added to the packet as the output data, and releases the encryption according to the encryption information (EMI). The descrambler 41 extends the packet that has been decrypted in this way in the time axis, and outputs the packet along with the encrypted information (EMI) by the transport stream TP.
[0053]
When the encryption information (EMI) is a logic “1, 0” indicating a generation in which copying is allowed only for one generation in the CGMS information (M-CGMS), the update circuit 43 sets the encryption information (EMI) to a logic “0”. , 1 ”, the copy generation of the digital video signal by the transport stream TP is updated and output only for the encryption information (EMI).
[0054]
The scrambler 44 encrypts and outputs the transport stream TP output from the descrambler 41 by the encryption method set for the optical disc apparatus 12. At this time, the scrambler 44 stops the process of the transport stream TP when the transport stream TP is transmitted in the mode C corresponding to copy prohibition by the encryption information (EMI). As a result, the optical disc apparatus 12 is configured to stop copying for copy-prohibited generations.
[0055]
The recording system 45 processes the output data of the scrambler 44 in a format suitable for recording on the optical disk 46 and then records it on the optical disk 46 together with the encryption information (EMI). As a result, in this embodiment, the reception result of the transport stream encrypted and transmitted as necessary can be recorded on the optical disk 46.
[0056]
As shown in FIG. 5, the reproduction system 48 receives and processes the return light obtained by irradiating the optical disk 46 with the light beam, and encrypts the transport stream TP and the encrypted information recorded on the optical disk 46. Play (EMI). The descrambler 49 decrypts the transport stream TP reproduced by the reproduction system 48 and outputs it.
[0057]
The scrambler 42 encrypts and outputs the transport stream TP output from the descrambler 49. At this time, similarly to the scrambler 30, the scrambler 42 encrypts the transport stream according to the reproduced encryption information (EMI).
[0058]
(2) Operation of the embodiment
In the above configuration, a program by digital satellite broadcasting (FIG. 2) is supplied to the broadcasting station 2 by a transport stream TP1 to TPN in the MPEG format via a server or the like, where it is time-division multiplexed and frequency multiplexed. After being uplinked to the satellite 3, the satellite 3 is downlinked and provided to each home 4.
[0059]
At this time, in the digital video signal, the conventional CGMS information (CGMS-D) (FIG. 7) indicating the copy generation is converted into the expanded CGMS information (M-CGMS) (FIG. 3), and each transport stream TP1 It is added to TPN. At this time, the expanded CGMS information (M-CGMS) is formed so as to indicate an extra copy generation by three copy generations in the conventional CGMS information (CGMS-D), and further the conventional CGMS information (CGMS). -D) is set so as to correspond to the generation (Free) in which no copy is restricted by the logic “0, 0”, and the generation in which only one generation is allowed by the logic “1, 0” (Copy Once) ), Generations (No Copy) that are not permitted to be copied by the logic “1,1” are assigned to the descriptors of the transport streams TP1 to TPN without any change in the logic level.
[0060]
When a program related to limited reception is transmitted in this way, the corresponding transport stream TP1 is encrypted by the scrambler 9 and transmitted.
[0061]
As a result, in the conventional CGMS information (CGMS-D), a digital video signal of a generation (Copy Once) in which only one generation of copying is permitted with a logic “1, 0”, and in a digital video signal of a program related to limited reception, In the transport stream, after the descriptor based on the extended CGMS information (M-CGMS) by the logic “1, 0” is added, the whole is encrypted and transmitted in the format of this digital satellite broadcasting. become.
[0062]
Each program sent in this way is demodulated in the channel selection circuit 21 of the IRD 11 (FIGS. 1 and 5), and the transport stream TP of the program desired by the user is demodulated. It is converted into a video signal and a digital audio signal. Further, the digital video signal and the digital audio signal are converted into an analog signal by a digital-analog conversion circuit and transmitted to an external device, so that a desired program can be auditioned through a monitor device, for example.
[0063]
At this time, the expanded CGMS information (M-CGMS) added to each transport stream TP is processed by the broadcast station 2 when the decoder 23 converts the transport stream TP into a digital video signal and a digital audio signal. Is converted into conventional CGMS information (CGMS-D). Further, this conventional CGMS information (CGMS-D) is converted into CGMS information (CGMS-A) indicating the copy generation of the video signal by an analog signal, and this CGMS information (CGMS-A) is output from this IRD 11 Is added to the video signal. In the IRD 11, copy guard processing is executed by the copy guard circuit 26 in accordance with the CGMS information (CGMS-A), thereby preventing illegal copying.
[0064]
That is, in the conventional CGMS information (CGMS-D) according to the above-described example, it is a digital video signal of a generation (Copy Once) in which copying is allowed only for one generation by logic “1, 0”, and the digital video of a program related to limited reception In the signal, after decryption by the descrambler 22, CGMS information (M-CGMS) expanded by logic “1, 0” is converted to conventional CGMS information (CGMS information by logic “1,0” in the decoder 23. -D), and this CGMS information (CGMS-D) is further converted into conventional CGMS information (CGMS-A) with logic "1,0". Thus, according to the CGMS information (CGMS-A), the digital video signal is converted into an analog video signal and output.
[0065]
In the IRD 11, the digital video signal and the digital audio signal demodulated by the decoder 23 in this manner are output to an external device through the interface 28 in a predetermined format. At this time, in the digital video signal, the conventional CGMS information (CGMS-D) converted from the expanded CGMS information (M-CGMS) is added and output. As a result, the copyright can be effectively protected by grasping the copy generation according to the CGMS information (CGMS-D) and restricting the copy in the external device.
[0066]
On the other hand, the transport stream TP demodulated by the descrambler 22 is output to the IEEE 1394 bus BUS via the interface 31, and is supplied to the optical disc device 12, other external devices, etc. via the IEEE 1394 bus BUS.
[0067]
At this time, the transport stream TP is set with encryption information (EMI) indicating an encryption mode in accordance with the extended CGMS information (M-CGMS) (FIG. 4), and according to the encryption information (EMI). It is encrypted. That is, in the conventional CGMS information (CGMS-D) according to the above-described example, if the digital video signal of the generation (Copy Once) in which only one generation is permitted by the logic “1, 0” is present, the presence / absence of the program related to the limited reception is present. Regardless of the encryption information (EMI) based on the logic “1, 0” is set, and encrypted by mode B encryption processing according to the encryption information (EMI) based on the logic “1, 0” and transmitted. .
[0068]
The transport stream TP encrypted and transmitted in this manner is decrypted by the descrambler 41 by processing according to the encryption information (EMI), and is recorded on the optical disk 46 by the subsequent scrambler 44. Is recorded on the optical disk 46 by the recording system 45.
[0069]
At this time, in the transport stream TP to which the extended CGMS information (M-CGMS) based on the logic “1, 1” that prohibits copying is added, the recording on the optical disk 46 is stopped, and the copy-prohibited generation is thereby stopped. Protects copyright by prohibiting copying.
[0070]
Further, at this time, the transport stream TP is updated with one generation of encryption information (EMI), and is recorded on the optical disk 46 together with the updated encryption information (EMI).
[0071]
That is, in the transport stream TP to which the extended CGMS information (M-CGMS) based on the logic “1, 0” according to the above example is added, the CGMS information (M-CGMS) permits copying only for one generation. By indicating the generation, in the update circuit 43, the encryption information (EMI) corresponding to the CGMS information (M-CGMS) is logical “0, 1” that prohibits copying from logical “1, 0”. Updated to be recorded on the optical disk 46.
[0072]
On the other hand, in the transport stream TP recorded on the optical disc 46 (FIG. 5), the encrypted transport stream TP is reproduced via the reproduction system 48, and the encryption of the transport stream TP is descrambler. It is released by 49. As a result, in the conventional CGMS information (CGMS-D) according to the above-described example, in a digital video signal of a generation (Copy Once) in which only one generation copy is permitted with a logic “1, 0”, a logic “1, 0”. Output from the descrambler 49 together with the encrypted information (EMI) of logic “0, 1” by the transport stream TP that is decrypted with the CGMS information (M-CGMS) expanded by Is done.
[0073]
When a read-only optical disc is loaded on the optical disc 46, the encrypted transport stream TP is reproduced in the same manner through the reproduction system 48, and the encryption of the transport stream TP is performed by the descrambler 49. Canceled. As a result, in this case, encryption is performed with the extended CGMS information (M-CGMS) added by the logic “1, 0” that permits copying only once or the logic “1, 1” that does not permit copying. The transport stream TP that has been canceled is output from the descrambler 49 together with the corresponding encryption information (EMI) of logic “1, 0” or logic “1, 1”.
[0074]
The transport stream TP reproduced from the optical disk 46 in this way is encrypted in the scrambler 42 according to the encryption information (EMI) indicating the encryption mode. Further, the data is output to the IEEE 1394 bus BUS via the interface 31, and is supplied to the IRD 11, other external devices, etc. via the IEEE 1394 bus BUS.
[0075]
In this case, in the extended CGMS information (M-CGMS) by the logic “1, 0” according to the example described with reference to FIG. 1, this logic “1, 0” is added to the transport stream TP. The transport stream TP is encrypted and transmitted in mode C corresponding to the encryption information (EMI) of logic “0, 1”.
[0076]
The transport stream TP sent to the bus BUS in this way is input to the descrambler 24 via the interface 31, where the encryption is released and the encryption information (EMI) is detected. In the subsequent decoder 23, the digital video signal and the digital audio signal are converted into a digital video signal and a digital audio signal, respectively, and the digital video signal and the digital audio signal are output to an external device via the interface 28, respectively. It is output via the copy guard circuit 26.
[0077]
At this time, when the extended CGMS information (M-CGMS) added to the transport stream TP is converted into a digital video signal and a digital audio signal by the decoder 23, a copy generation is generated according to the encryption information (EMI). After being updated, it is converted into CGMS information (CGMS-D) defined for the digital signal. In this conversion, in the transport stream TP transmitted from the optical disc apparatus 12 in this way, there are generations that are reproduced from the optical disc 46 that is not defined in the CGMS information (CGMS-D) and are prohibited from being copied thereafter. As a result, the logic “0, 1” relating to this generation is similarly converted into CGMS information (CGMS-D) based on the logic “1, 1” that prohibits subsequent copying.
[0078]
As a result, the transport stream output from the optical disc apparatus 12 in this way is processed in the same manner as the transport stream received by the IRD 11 and is processed by the digital video signal and the digital audio signal, or by the video signal and the audio signal by the analog signal. Output to an external device.
[0079]
(3) Effects of the embodiment
According to the above configuration, the copy generation that can be expressed by the extended CGMS information (M-CGMS) by defining a code that is not defined in the conventional CGMS information (CGMS-D) is expanded and necessary. By converting these generation information accordingly, the copy generation of the digital signal can be easily managed when the encryption mode is switched according to the copy generation of the digital signal.
[0080]
(4) Other embodiments
In the above-described embodiment, when a digital video signal is transmitted by digital satellite broadcasting, the case of encryption by a format by a broadcasting station is described. However, the present invention is not limited to this, and the present invention is not limited to this. The encryption mode may be switched by the CGMS information (M-CGMS). In this way, it becomes possible to primarily manage the processing of the encrypted transport stream by various digital satellite broadcasting systems on the IRD side.
[0081]
In the above-described embodiment, the case has been described in which the extended CGMS information (M-CGMS) is defined so as to define an undefined code in the conventional CGMS information (CGMS-D) of 2 bits. The present invention is not limited to this. For example, CGMS information (M-CGMS) extended by a 3-bit code may be defined with respect to conventional CGMS information (CGMS-D) of 2 bits. In this way, the copy generation can be managed more finely.
[0082]
Furthermore, in the above-described embodiment, the case where the transport stream is recorded on the optical disk device by applying to the digital satellite broadcasting system has been described, but the present invention is not limited to this, and the transport stream is recorded on, for example, a magnetic tape. It can be widely applied to cases.
[0083]
In the above-described embodiments, the case where the transport stream is transmitted by IEEE 1394 has been described. However, the present invention is not limited to this, and when the transport stream is transmitted by various interfaces, the optical disk, the magnetic tape, and the magnetic disk. The present invention can be widely applied when transport streams are transmitted by a recording medium such as the above.
[0084]
In the above-described embodiment, the case where the digital video signal is transmitted by managing the encryption process based on the CGMS information as the generation information has been described. However, the present invention is not limited to the case where the encryption process is managed. The present invention can be widely applied to various management of digital video signals by generation information.
[0085]
Further, in the above-described embodiment, the case where the digital video signal is transmitted by the transport stream has been described. However, the present invention is not limited to this, and when the digital video signal is transmitted by various formats, the digital audio signal or the like is further transmitted. The present invention can be widely applied when transmitting various digital signals.
[0086]
【The invention's effect】
As described above, according to the present invention, the first generation information is defined so as to be extended with respect to the second generation information indicating the copy generation of the unencrypted digital signal, and if necessary, By converting these generation information, the copy generation of the digital signal can be easily managed when the encryption mode is switched according to the copy generation of the digital signal.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a receiving side applied to a satellite broadcasting system according to an embodiment of the present invention.
FIG. 2 is a block diagram showing an overall configuration of a satellite broadcasting system.
FIG. 3 is a chart showing descriptors added to a transport stream.
FIG. 4 is a chart showing encryption information.
FIG. 5 is a block diagram for explaining a transport stream reproduced by comparison with FIG. 1;
FIG. 6 is a chart for explaining a process of changing expanded CGMS information into conventional CGMS information.
FIG. 7 is a chart showing conventional CGMS information.
[Explanation of symbols]
1 ... satellite broadcasting system, 2 ... broadcast station, 3 ... satellite, 4 ... home, 9, 22, 30, 42, 44 ... scrambler, 24, 41, 49 ... descrambler, 46 ... optical disk

Claims (6)

Encryption means for generating an encrypted digital signal by encrypting the digital signal and the first generation information in an encryption mode corresponding to the first generation information added to the digital signal;
Transmission means for sending encryption information indicating the encryption mode and the encrypted digital signal;
The first generation information is
Information indicating the copy generation of the digital signal;
In place of the second generation information indicating the copy generation of the unencrypted digital signal, the information is set by extending the second generation information .
A generation provided in the second generation information and a generation in which subsequent copying is prohibited are provided,
The generations classified into the generations for which copying provided in the second generation information is prohibited are the generations for which copying is prohibited from the beginning by the generations for which copying is prohibited, and the generations for which the subsequent copying is prohibited. An apparatus for transmitting a digital signal, characterized in that the information is classified into generations for which copying is prohibited by copying according to (1) . Encrypting the digital signal and the first generation information by an encryption mode corresponding to the first generation information added to the digital signal to generate an encrypted digital signal;
Sending the encryption information indicating the encryption mode and the encrypted digital signal,
The first generation information is
Information indicating the copy generation of the digital signal;
In place of the second generation information indicating the copy generation of the unencrypted digital signal, the information is set by extending the second generation information .
A generation provided in the second generation information and a generation in which subsequent copying is prohibited are provided,
The generations classified into the generations for which copying provided in the second generation information is prohibited are the generations for which copying is prohibited from the beginning by the generations for which copying is prohibited, and the generations for which the subsequent copying is prohibited. A method for transmitting a digital signal, characterized in that the information is classified into generations for which copying is prohibited by copying according to (1) . Reproducing means for reproducing an encrypted digital signal from a recording medium;
Decryption means for decrypting the encrypted digital signal; and
Information conversion means for converting the first generation information added to the digital signal decrypted by the decryption means into second generation information;
The first generation information is
Information indicating a copy generation of the encrypted digital signal,
Instead of the second generation information indicating the copy generation of the unencrypted digital signal, the information is set by extending the second generation information,
A generation provided in the second generation information and a generation in which subsequent copying is prohibited are provided,
The generations classified into the generations for which copying provided in the second generation information is prohibited are the generations for which copying is prohibited from the beginning by the generations for which copying is prohibited, and the generations for which the subsequent copying is prohibited. An apparatus for transmitting a digital signal, characterized in that the information is classified into generations for which copying is prohibited by copying according to (1) . Play the encrypted digital signal from the recording medium,
Decrypting the encrypted digital signal;
Converting the first generation information added to the decrypted digital signal into second generation information;
The first generation information is
Information indicating a copy generation of the encrypted digital signal,
Instead of the second generation information indicating the copy generation of the unencrypted digital signal, the information is set by extending the second generation information,
A generation provided in the second generation information and a generation in which subsequent copying is prohibited are provided,
The generations classified into the generations for which copying provided in the second generation information is prohibited are the generations for which copying is prohibited from the beginning by the generations for which copying is prohibited, and the generations for which the subsequent copying is prohibited. A method for transmitting a digital signal, characterized in that the information is classified into generations for which copying is prohibited by copying according to (1) . A digital signal recording medium for recording an encrypted digital signal,
The digital signal is
Encrypted by the encryption mode according to the added first generation information, recorded together with the encryption information indicating the encryption mode,
The first generation information is
Information indicating a copy generation of the encrypted digital signal,
Instead of the second generation information indicating the copy generation of the unencrypted digital signal, the information is set by extending the second generation information,
A generation provided in the second generation information and a generation in which subsequent copying is prohibited are provided,
The generations classified into the generations for which copying provided in the second generation information is prohibited are the generations for which copying is prohibited from the beginning by the generations for which copying is prohibited, and the generations for which the subsequent copying is prohibited. A digital signal recording medium, characterized in that the information is classified into generations for which copying is prohibited by copying according to (1) . The digital signal recording medium according to claim 5, wherein the digital signal is a digital video signal.

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