JP4821838B2 - Format conversion apparatus, format conversion method, format conversion program, and format conversion system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a data transfer system which can correct the differences of packet formats. <P>SOLUTION: When transmitting data from an IEEE1394 apparatus connected to an IEEE1394 cable 6 to a USB apparatus 7 connected to a USB cable 8, a packet of the IEEE1394-type transferred from an IEEE1394 apparatus 5 and identification information for identifying the USB apparatus defined by each USB apparatus 7 are inserted into the packet of the USB and transferred to the USB. By this means, the differences between the packet formats can be corrected, and DTCP, an illegal copy preventing technology of the IEEE1394, can be applied to the USB. <P>COPYRIGHT: (C)2009,JPO&amp;INPIT

Description

  The present invention relates to a data transfer system for transferring copyright information between devices connected to different buses, a communication device, a wireless device, an unauthorized copy prevention method, and a recording medium on which a program is recorded. The present invention relates to a data transfer system, a communication device, a wireless device, an unauthorized copy prevention method, and a recording medium on which a program is recorded, in which DTCP (Digital Transmission Content Protection), which is a technical standard, can be applied to other different buses.

  In recent years, IEEE1394 (IEEE Standard for a) has been used as an interface for connecting personal computers (hereinafter referred to as PCs), PC peripherals such as printers and scanners, digital video disks (hereinafter referred to as DVDs), digital video cameras, and the like. High Performance Serial Bus) and USB 1.1 (Universal Serial Bus Revision 1.1) are attracting attention.

  Many products have been put on the market for easy connection to IEEE 1394 and USB 1.1. IEEE 1394 has a maximum transfer rate of 400 megabits per second (Mbps), whereas USB 1.1 has a maximum transfer rate of 12 megabits per second (Mbps).

  Also, USB allows only star-like topologies centered on a host (usually a PC is the host), and serves as an interface for connecting low-speed PC peripherals such as a keyboard, mouse, and telephone. Has been used.

  On the other hand, IEEE 1394 can be used as an interface for applications that handle large volumes of data such as moving images, as a matter of course, such low speed devices as described above. Was separated from IEEE1394.

  Recently, however, there has been a movement to standardize USB 2.0, which speeds up USB 1.1 and newly increases the maximum transfer speed of current USB 1.1 by 40 times.

  The USB 2.0 has a maximum transfer rate of 480 megabits per second (Mbps) and the current IEEE 1394 maximum transfer rate of 400 megabits per second (Mbps), which are almost equivalent in terms of transfer rate.

  As a result, data can be transferred in real time from a device connected by IEEE1394 to a device connected by USB.

  As a conventional example 1 having a technical field similar to that of the present invention, there is a bus data transfer system disclosed in Japanese Patent Laid-Open No. 11-145959.

  This conventional example proposes a resource acquisition and data transfer method when a plurality of buses having different resource acquisition methods are connected. As shown in FIG. 15, a PC 50, a camera 51, and a video phone are used as USB devices. 53 is connected, a satellite broadcast receiver (hereinafter referred to as IRD) 54 and a recorder (hereinafter referred to as DVCR) 55 are connected as IEEE 1394 devices, and an adapter 52 is connected as a device that mediates between these USB devices and IEEE 1394 devices. In a system in which the PC 50 serves as a host for data exchange with USB, when an instruction is given from the user, the PC 50 first makes an isochronous transfer request to the USB device after initial setting of IEEE 1394. Issue this request and get it. Next, the adapter 52 is requested to connect the pipe to the USB, and when this is successful, isochronous transfer is started. The adapter 52 receives the data on the IEEE 1394 bus and transfers the received data to the PC 50. Alternatively, the PC 50 receives the image data from the camera 51 and sends it to the adapter 52. The adapter 52 sends this to the IEEE 1394 side. .

Japanese Patent Laid-Open No. 11-145995

  However, although IEEE 1394 defines a standard for copyright protection of digital content (hereinafter referred to as DTCP: Digital Tansmission Content Protection) and prevents unauthorized copying, USB has a clear technology for preventing unauthorized copying. Not.

  As shown in FIG. 16, DTCP is a technique for receiving a key or algorithm necessary for authentication from a license management station and encrypting and transmitting / receiving data flowing on the IEEE 1394 serial bus.

  When transmitting data, a transmitting device connected by an IEEE 1394 serial bus refers to data copy control information (hereinafter referred to as CCI: Copy Control Information), and depending on the CCI, authentication with a receiving device is required. There are four types of CCI: copy disabled, copy only once, copy disabled further, and copy enabled. DTCP is applied except for copy enabled.

  When a data receiving device requests data from a transmitting device connected via an IEEE 1394 serial bus, the data receiving device requests authentication from the transmitting device. Using this request as a trigger, authentication is performed between the transmitting device and the receiving device. When the authentication is successful, the transmitting device and the receiving device share a key, and the transmitting device encrypts data with this key and transmits the encrypted data on the IEEE 1394 serial bus. The receiving device restores the encrypted data with the key shared by the authentication.

  When DTCP, which is an existing illegal copy prevention technology, is applied to USB, there are the following problems.

  First, the packet format of IEEE 1394 and USB are different, and the packet header function of the USB (for example, a bit indicating copy management information, a bit indicating key change timing, etc.) possessed by DTCP is owned by the USB packet header. Not done.

  In addition, USB supports data transfer between a host (usually a PC) and a device, but data transfer between USB devices is not defined. Therefore, DTCP that requires communication between devices cannot be applied as it is.

To achieve the object according, format conversion apparatus of the present application, the IEEE1394 device connected to the IEEE1394 bus, formats between devices connected to said bus other than the IEEE1394 bus for transmitting and receiving data with the IEEE1394 device A conversion device,
The format conversion apparatus applies the IEEE 1394 packet format transmitted from the IEEE 1394 equipment to a data area of a data packet of a format corresponding to a bus other than the IEEE 1394 bus of the device, and defines the device defined for each device. It is characterized in that identification information for identifying is incorporated .

Also, the format conversion method of the present application, the IEEE1394 device connected to the IEEE1394 bus, format conversion method in the format converter between devices connected to said bus other than the IEEE1394 bus for transmitting and receiving data with the IEEE1394 device Because
The format conversion apparatus applies an IEEE 1394 format packet format transmitted from the IEEE 1394 equipment to a data area of a data packet in a format corresponding to a bus other than the IEEE 1394 bus of the device, and defines the format defined for each device. It is characterized by incorporating identification information for identifying a device.

A computer-readable recording medium on which the format conversion program of the present application is recorded is between an IEEE 1394 device connected to the IEEE 1394 bus and a device connected to a bus other than the IEEE 1394 bus that transmits and receives data to and from the IEEE 1394 device. a computer-readable recording medium recording the format conversion program in the format conversion apparatus in,
The format conversion apparatus applies the IEEE 1394 packet format transmitted from the IEEE 1394 equipment to a data area of a data packet of a format corresponding to a bus other than the IEEE 1394 bus of the device, and defines the device defined for each device. It is characterized in that identification information for identifying is incorporated .

Also, the format conversion system of the present application is a format conversion system between devices connected to said bus other than IEEE1394 bus for the IEEE1394 device connected to the IEEE1394 bus, the transmission and reception of data with the IEEE1394 device,
The format conversion system applies an IEEE 1394 packet format transmitted from the IEEE 1394 equipment to a data area of a data packet in a format corresponding to a bus other than the IEEE 1394 bus of the device, and defines the device defined for each device. It is characterized in that identification information for identifying is incorporated .

  The present invention defines a copy management information which becomes a problem when DTCP is applied to a bus other than the IEEE 1394 bus, and a data transfer system capable of correcting a difference in packet format by defining data transfer between devices, An object is to provide a communication device, a wireless device, an unauthorized copy prevention method, and a recording medium on which a program is recorded.

  Next, embodiments of a data transfer system, a wireless device, an unauthorized copy prevention method thereof, and a recording medium on which the unauthorized copy prevention program is recorded will be described in detail with reference to the accompanying drawings.

  1 to 14 show an embodiment of a data transfer system, a wireless device, an unauthorized copy prevention method thereof, and a recording medium recording the unauthorized copy prevention program of the present invention.

  As shown in FIG. 1, in the embodiment according to the present invention, an IEEE 1394 adapter 3 and a USB adapter 4 are connected to a personal computer (hereinafter referred to as a PC) 1 via a PCI (Peripheral Component Interconnect) bus 2. . The IEEE 1394 adapter 3 is connected to an IEEE 1394 cable 6 to which the IEEE 1394 equipment 5A, the IEEE 1394 equipment 5B, and the IEEE 1394 equipment 5C are respectively connected. The USB adapter 4 is connected to the USB device 7A, USB device 7B, USB device 7C, and USB device 7D in a tree shape by the USB cable 8.

  The PC 1 is a device equipped with an interface between IEEE1394 and USB, and the PC1 serves as a USB host.

  The IEEE 1394 device 5A, the IEEE 1394 device 5B, and the IEEE 1394 device 5C are devices having only an IEEE 1394 interface (that is, an IEEE 1394 device), and the USB device 7A, the USB device 7B, the USB device 7C, and the USB device 7D are USB interfaces. It is a device with only. Note that the IEEE 1394 device 5 and the USB device 7 may be a device having a USB interface in the IEEE 1394 device or a device having an IEEE 1394 interface in the USB device.

  FIG. 2 shows a configuration when specific devices are applied to the IEEE 1394 equipment 5 and the USB equipment 7 shown in FIG. As shown in the figure, a digital VHS (hereinafter referred to as D-VHS) 9 and a digital satellite broadcast receiver (hereinafter referred to as IRD: Integrated Receiver Decoder) 10 are connected as IEEE 1394 equipment, and a keyboard as a USB equipment. 11, a mouse 12, a printer 13, and a hard disk (hereinafter referred to as HDD: Hard Disk Drive) 14 are connected.

  FIG. 3 shows a packet format of isochronous transfer used for data transfer in IEEE1394. As shown in the figure, the packet format for isochronous transfer includes fields of Data Length, Tag, channel, Tcode, EMI, Odd / Even, SY, Header_CRC, DataField, and Data_CRC.

  Data Length is a field that defines the byte length of the data field following the header.

  Tag is a field indicating the format of the isochronous packet.

  The channel is a field indicating a channel number used for identifying an isochronous packet.

  Tcode (Transaction code) is a field indicating a code indicating a packet type.

  EMI (Encryption Mode Indicator) is a field indicating the contents of CCI.

  Odd / Even is a field indicating the change timing of the encryption key.

  SY (Synchronization code) is a field used to exchange synchronization information such as video and audio between the transmission node and the reception node.

  Header_CRC is a field indicating CRC (cyclic redundancy check) for header information.

  Data is a field into which payload data is inserted.

  Data_CRC is a field to which CRC for the data payload is added.

  FIG. 4 shows an asynchronous (write request) transfer packet format used for authentication. As shown in the figure, the packet format of asynchronous transfer includes destination_ID, tl, rt, tcode, pri, source_ID, packet type specific information, data_length, extended_tcode, header_CRC, header_CRC, header_CRC, header_CRC, header_CRC, header_CRC, header_CRC, header_CRC, header_CRC .

  The destination_ID (Destination identifier) is a field indicating the ID of the node to which the packet is transmitted.

  tl (Transaction label) is a field indicating a label for recognizing a match between a pair of transactions of a request packet and a response packet.

  rt (Retry code) is a field indicating information on a retry method when a busy Acknowledge packet is received.

  tcode (Transaction code) is a field indicating the type code of the transaction packet.

  pri (Priority) is all 0 in fair arbitration (arbitration that guarantees bus access fairly to all transmission request nodes on the bus).

  The source_ID is a field indicating ID information of the packet transmission source node.

  The packet type specific information is a field indicating information specific to each packet type, and destination_offset (indicates a target address in the register space of the packet destination node), rcode (Response code) and reserved (response code and reservation) Field} and the like are inserted.

  data_length indicates the length (bytes) of the data payload in the packet.

  extended_tcode is meaningful only when the packet is a lock packet, and indicates the type of the lock.

  In IEEE 1394, the maximum transfer size of asynchronous transfer is determined for each transfer speed, and is 512 bytes for S100 (98.304 Mbps), 1024 bytes for S200 (196.608 Mbps), and 2048 bytes for S400 (393.216 Mbps). It has become.

  FIG. 5 shows packet formats of isochronous transfer used for USB data transfer and bulk transfer used for authentication (see Universal Serial Bus Specification Revision 1.1). As shown in the figure, isochronous transfer and bulk transfer packets are composed of fields of SYNC (Synchronous Idle), PID (Packet ID), DATA, and CRC (Cyclic Redundancy Check Code) 16. This data packet is defined so that data of up to 1024 bytes can be transferred.

  In this embodiment configured as described above, DTCP used in IEEE 1394 is applied to a USB cable so that copyright information can be transmitted and received between devices connected to different buses such as an IEEE 1394 cable and a USB cable. It is characterized by doing.

  The above-described protocol functions required by DTCP are possessing a packet header indicating copy management information and being defined so that devices can communicate with each other.

  As is clear from FIGS. 3, 4 and 5, the packet format is different between IEEE1394 and USB. In order to apply DTCP to USB, it is necessary to first add 2 bits indicating CCI and 1 bit indicating key change timing at the time of data transfer.

  Therefore, in the present embodiment, when data is transferred from the IEEE 1394 device to the USB device, the IEEE 1394 adapter 3 and the USB adapter 4 in the middle of the PC 1 in the data area of the USB data packet as shown in FIG. Apply the following packet format. That is, the PC 1 serves as a format conversion adapter between IEEE1394 and USB.

  At the time of data transfer from the IEEE 1394 device to the USB device, the IEEE 1394 packet shown in FIG. 3 enters the data area of the USB packet format as shown in FIG. This makes it possible to realize a bit indicating CCI and a bit indicating a key change timing even in a USB data packet. Note that the IEEE 1394 packet shown in FIG.

  In addition, in transferring data from a USB device to an IEEE 1394 device, 2 bits indicating CCI and a bit indicating a key change timing are added, so that each USB device has the IEEE 1394 shown in FIG. 3 in the data area of the packet. A USB packet (FIG. 6) to which the packet format is applied is generated. Also, the PC 1 serving as a packet format conversion adapter between IEEE 1394 and USB takes out a packet in IEEE 1394 format from the data area of the USB packet shown in FIG. 6, and transfers it to the IEEE 1394 equipment side.

  In USB, communication between hosts and devices is not defined. For this reason, it is impossible to apply DTCP, which requires communication between devices.

  Therefore, in order to apply DTCP, as shown in FIG. 6, a USB device identifier (called Destination ID) is newly defined in the USB packet to realize communication between devices.

  This is, for example, an 8-bit identifier in which one value is assigned to one device in the USB bus, and is assumed to be assigned to each device by the host when the bus is initialized. By using this identifier, devices can communicate with each other.

  In the embodiment shown in FIG. 2, when the PC 1 (host) initializes the bus, the keyboard is “1”, the mouse is “2”, the HDD is “3”, and the printer is “4”. Assign an identifier. As a result, data can be directly sent from the HDD “3” to the printer “4”. Each device holds the identifier assigned by the host in the device descriptor. The device descriptor describes general information of the USB device and has a structure having defined data.

  As described above, in the data transfer from the IEEE 1394 device to the USB device, the PC 1 generates the USB packet in which the IEEE 1394 format data transferred from the IEEE 393 device is applied to the USB data area, and transfers it to the USB device side. When transferring data from the USB device to the IEEE 1394 device, each USB device generates a USB packet in which the data area of the packet is generated in the IEEE 1394 packet format. Further, when the bus is initialized, the PC 1 assigns an identifier to each USB device, so that it is possible to apply DTCP between a device connected to the IEEE1394 bus and a device connected to the USB bus. Therefore, unauthorized copying of information transmitted and received between the IEEE 1394 device and the USB device can be prevented.

  In addition, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a USB device connected to the USB bus, the existing DTCP standardized by IEEE 1394 can be applied on the USB side. Accordingly, it is not necessary to apply different illegal copy prevention technology for each bus, so that it is possible to reduce the cost of constructing a system for transmitting and receiving copyright information.

  Next, an operation when DTCP is applied between the IEEE 1394 device and the USB device will be described with reference to FIG.

  The case where data is copied from the IRD 10 connected to the IEEE 1394 bus to the HDD 14 connected to the USB bus in the configuration shown in FIG. 2 will be described.

  The HDD 14 requests the IRD 10 to transmit data via the USB adapter 4 and the IEEE 1394 adapter 3.

  The PC 1 has a “connection establishment function” for connecting a signal path between an IEEE 1394 device and a USB device, a “function for maintaining a connection” for maintaining the connected signal path, and a packet format conversion from IEEE 1394 to USB. In contrast, it has a function of packet format conversion from USB to IEEE 1394, and constantly monitors data exchange between the IEEE 1394 device and the USB device.

  The IRD 10 checks the CCI of the data requested from the HDD 14 and transmits the data to the HDD as it is if the data is not subject to copyright protection.

  If the data requested from the HDD 14 is data subject to copyright protection, an authentication request from the HDD 14 is awaited. In response to the authentication request from the HDD 14, the HDD 14 and the IRD 10 obtain a common key.

  The IRD 10 encrypts data using a key shared with the HDD 14, and transmits the encrypted data to the HDD 14 via the IEEE 1394 adapter 3, the PC 1, and the USB adapter 4. At this time, when the PC 1 converts the IEEE 1394 format data into the USB format data, the IEEE 1394 packet format is applied to the data portion of the USB data packet. Therefore, a bit indicating CCI and a bit indicating key change timing can be realized even in a USB data packet, and copyright information can be transmitted and received between different buses.

  When transferring copyright protection target information from the USB device to the IEEE 1394 device, the PC 1 takes out the data generated in the IEEE 1394 packet format by the USB device and inserted into the USB data area, and the taken out data is IEEE 1394. Transfer to the device side.

  With the above-described operation, copyright protection target data can be transmitted and received between the IEEE 1394 device and the USB device.

  Next, a second embodiment according to the present invention will be described with reference to FIG.

  The second embodiment according to the present invention is characterized in that, as shown in FIG. 7, an illegal copy protection bit indicating a CCI or key change timing and a “DESTINATION ID” are newly defined in a USB packet. . Therefore, it is possible to apply the IEEE1394 illegal copy protection technology even in the USB packet format. Further, as in the first embodiment described above, when data is transferred from the IEEE 1394 device to the USB device, the PC 1394 serving as the USB host converts the IEEE 1394 format data transferred from the IEEE 1394 device into the data of the USB packet. There is no need to perform transformations to be incorporated into the area. In the embodiment shown in FIG. 7, the illegal copy protection bit indicating the CCI and key change timing is defined as 8 bits, but the number of bits is not limited to 8 and can be appropriately implemented. It is.

  Next, a third embodiment according to the present invention will be described with reference to FIG. The third embodiment of the present invention applies the D1394 technology of IEEE 1394 to the PCI bus, and copyright information is transmitted between the IEEE 1394 equipment connected to the IEEE 1394 bus and the device connected to the PCI bus using the DTCP technology. It is characterized by mutual transmission and reception.

  In order to achieve this object, when the copyright information is transmitted from the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6 to the device 22 connected to the PCI bus 21 as shown in FIG. In the intermediate format conversion adapter 20 with the PCI bus compatible device 22, the IEEE 1394 packet transferred from the IEEE 1394 device 5 is inserted into the data portion of the data packet that can be transferred via the PCI bus. Further, the format conversion adapter 20 inserts “Destination ID” which is an identifier of a device on the PCI bus into this data packet.

  Further, when data is transferred from the device 22 connected to the PCI bus to the IEEE 1394 equipment 5 connected to the IEEE 1394 bus, the data to be inserted into the data area of the data packet is transferred from the device 22 connected to the PCI bus 21. Generated in the IEEE 1394 packet format. In addition, an identifier “Destination ID” for identifying a destination device is incorporated in the data packet. Data formed in such a format is transferred to the format conversion adapter 20, where data generated in the IEEE 1394 format is taken out from the data area of the data packet and transferred to the IEEE 1394 equipment side.

  In this way, it is possible to apply DTCP between the IEEE 1394 device connected to the IEEE 1394 bus and the device connected to the PCI bus, and transmission / reception is performed between the IEEE 1394 device and the PCI bus compatible device. Unauthorized copying of information can be prevented.

  In addition, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a device connected to the PCI bus, the existing DTCP standardized by IEEE 1394 can be applied to the PCI side. Accordingly, it is not necessary to apply different illegal copy prevention technologies for each bus, and thus it is possible to reduce the cost for constructing a system for transmitting and receiving copyright information.

  Next, a fourth embodiment according to the present invention will be described. The fourth embodiment according to the present invention is characterized in that an illegal copy protection bit indicating a CCI or key change timing and a “Destination ID” are newly defined in a PCI packet. This makes it possible to apply the IEEE1394 illegal copy protection technology even in the PCI packet format.

  Next, a fifth embodiment according to the present invention will be described with reference to FIG. The fifth embodiment of the present invention applies the IEEE 1394 DTCP technology to the PCMCIA bus, and uses the DTCP technology between the IEEE 1394 equipment connected to the IEEE 1394 bus and the device connected to the PCMCIA bus to obtain copyright information. It is characterized by mutually transmitting and receiving.

  In order to achieve this object, when the copyright information is transmitted from the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6 to the device 25 connected to the PCMCIA bus 24 as shown in FIG. 9, the IEEE 1394 equipment 5 and the PCMCIA In the intermediate format conversion adapter 23 with the bus corresponding device 25, the IEEE 1394 packet transferred from the IEEE 1394 device 5 is inserted into the data portion of the data packet that can be transferred through the PCMCIA bus. Further, the format conversion adapter 23 inserts “Destination ID” which is an identifier of the device on the PCMCIA bus 24 into this data packet.

  When data is transferred from the device 25 connected to the PCMCIA bus 24 to the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6, the data is inserted into the data area of the data packet in the device 25 connected to the PCMCIA bus 24. Data is generated in the IEEE 1394 packet format. In addition, an identifier “Destination ID” for identifying a destination device is incorporated in the data packet. The data formed in such a format is transferred to the format conversion adapter 23, where data generated in the IEEE 1394 format is taken out from the data area of the data packet and transmitted to the IEEE 1394 equipment 5 side.

  In this way, it is possible to apply DTCP between the IEEE 1394 device connected to the IEEE 1394 bus and the device connected to the PCMCIA bus, and transmission / reception is performed between the IEEE 1394 device and the PCMCIA bus compatible device. Unauthorized copying of information can be prevented.

  In addition, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a device connected to the PCMCIA bus, the existing DTCP standardized by IEEE 1394 can be applied to the PCMCIA side. Accordingly, it is not necessary to apply different illegal copy prevention technologies for each bus, and thus it is possible to reduce the cost for constructing a system for transmitting and receiving copyright information.

  Next, a sixth embodiment according to the present invention will be described. The sixth embodiment according to the present invention is characterized in that an illegal copy protection bit indicating a CCI or key change timing and a “Destination ID” defined in the above-described embodiment are newly defined in a PCMCIA packet. As a result, the IEEE1394 illegal copy protection technology can be applied even in the packet format of PCMCIA.

  Next, a seventh embodiment according to the present invention will be described with reference to FIG. The seventh embodiment according to the present invention applies the IEEE 1394 DTCP technology to the SCSI bus, and copyright information between the IEEE 1394 equipment connected to the IEEE 1394 bus and the device connected to the SCSI bus using the DTCP technology. It is characterized by mutually transmitting and receiving.

  In order to achieve this object, when the copyright information is transmitted from the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6 to the device 28 connected to the SCSI bus 27 as shown in FIG. In the format conversion adapter 26 intermediate to the SCSI bus compatible device 28, the IEEE packet transferred from the IEEE 1394 device is inserted into the data portion of the data packet that can be transferred by the SCSI bus 27. Further, the format conversion adapter 26 inserts “Destination ID” which is an identifier of a device on the SCSI bus into this data packet.

  When data is transferred from the device 28 connected to the SCSI bus to the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6, the data inserted in the data area of the data packet in the device 28 connected to the SCSI bus 27. Are generated in the IEEE 1394 packet format. In addition, an identifier “Destination ID” for identifying a destination device is incorporated in the data packet. The data formed in such a format is transferred to the format conversion adapter 26, where the data generated in the IEEE 1394 format is taken out from the data area of the data packet and transmitted to the IEEE 1394 equipment 5 side.

  In this way, it is possible to apply DTCP between an IEEE 1394 device connected to the IEEE 1394 bus and a device connected to the SCSI bus, and information transmitted and received between the IEEE 1394 device and the SCSI device can be transmitted. Unauthorized copying can be prevented.

  In addition, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a device connected to the SCSI bus, the existing DTCP standardized by IEEE 1394 can be applied to the SCSI side. Accordingly, it is not necessary to apply different illegal copy prevention technologies for each bus, and thus it is possible to reduce the cost for constructing a system for transmitting and receiving copyright information.

  Next, an eighth embodiment according to the present invention will be described. The eighth embodiment according to the present invention is characterized in that an illegal copy protection bit indicating a CCI or key change timing and a “Destination ID” defined in the above-described embodiment are newly defined in a SCSI packet. As a result, the IEEE1394 illegal copy protection technology can be applied even in the SCSI packet format.

  Next, a ninth embodiment according to the present invention will be described with reference to FIG. The ninth embodiment of the present invention applies the IEEE 1394 DTCP technology to the ISA bus, and uses the DTCP technology between the IEEE 1394 equipment connected to the IEEE 1394 bus and the device connected to the ISA bus to obtain copyright information. It is characterized by mutually transmitting and receiving.

  In order to achieve this object, when the copyright information is transmitted from the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6 to the device 31 connected to the ISA bus 30 as shown in FIG. In an intermediate format conversion adapter 29 with the ISA bus compatible device 31, the IEEE packet transferred from the IEEE 1394 device 5 is inserted into the data portion of the data packet that can be transferred by the ISA bus 30. Further, the format conversion adapter 29 inserts “Destination ID” which is an identifier of the device on the ISA bus 30 into this data packet.

  Further, when data is transferred from the device 31 connected to the ISA bus 30 to the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6, the data is inserted into the data area of the data packet in the device 31 connected to the ISA bus 30. Data is generated in the IEEE 1394 packet format. In addition, an identifier “Destination ID” for identifying a destination device is incorporated in the data packet. The data formed in such a format is transferred to the format conversion adapter 29, where data generated in the IEEE 1394 format is taken out from the data area of the data packet and transmitted to the IEEE 1394 equipment 5 side.

  In this way, it is possible to apply DTCP between an IEEE 1394 device connected to the IEEE 1394 bus and a device connected to the ISA bus, and information transmitted and received between the IEEE 1394 device and the ISA device can be transmitted. Unauthorized copying can be prevented.

  In addition, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a device connected to the ISA bus, the existing DTCP standardized by IEEE 1394 can be applied to the ISA side. Accordingly, it is not necessary to apply different illegal copy prevention technologies for each bus, and thus it is possible to reduce the cost for constructing a system for transmitting and receiving copyright information.

  Next, a tenth embodiment according to the present invention will be described. The tenth embodiment according to the present invention is characterized in that an illegal copy protection bit indicating a CCI or key change timing and a “Destination ID” defined in the above-described embodiment are newly defined in an ISA data packet. Yes. As a result, the IEEE1394 illegal copy protection technology can be applied even in the ISA packet format.

  Next, an eleventh embodiment according to the present invention will be described with reference to FIG. In the eleventh embodiment of the present invention, the DTCP technology of IEEE 1394 is applied to the C bus, and the copyright information is used between the IEEE 1394 equipment connected to the IEEE 1394 bus and the device connected to the C bus using the DTCP technology. It is characterized by mutually transmitting and receiving.

  In order to achieve this object, when copyright information is transmitted from the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6 to the device 34 connected to the C bus 33 as shown in FIG. In the intermediate format conversion adapter 32 with the C bus compatible device 34, the IEEE 1394 packet transferred from the IEEE 1394 device 5 is inserted into the data portion of the data packet that can be transferred through the C bus 33. Further, the format conversion adapter 32 inserts “Destination ID” which is the identifier of the device on the C bus 33 into this data packet.

  Further, when data is transferred from the device 34 connected to the C bus 33 to the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6, the data is inserted into the data area of the data packet in the device 34 connected to the C bus 33. Data is generated in the IEEE 1394 packet format. In addition, an identifier “Destination ID” for identifying a destination device is incorporated in the data packet. The data formed in such a format is transferred to the format conversion adapter 32, where data generated in the IEEE 1394 format is taken out from the data area of the data packet and transmitted to the IEEE 1394 equipment 5 side.

  In this way, it is possible to apply DTCP between the IEEE 1394 device connected to the IEEE 1394 bus and the device connected to the C bus, and transmission / reception is performed between the IEEE 1394 device and the C bus compatible device. Unauthorized copying of information can be prevented.

  In addition, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a device connected to the C bus, the existing DTCP standardized by IEEE 1394 can be applied to the C side. Accordingly, it is not necessary to apply different illegal copy prevention technologies for each bus, and thus it is possible to reduce the cost for constructing a system for transmitting and receiving copyright information.

  Next, a twelfth embodiment according to the present invention will be described. In the twelfth embodiment according to the present invention, the illegal copy protection bit indicating the CCI and key change timing and the “Destination ID” defined in the above-described embodiment are newly defined in the packet on the C bus. It is a feature. As a result, the illegal copy protection technology of IEEE1394 can be applied even with the packet format of the C bus.

  Next, a thirteenth embodiment according to the present invention will be described with reference to FIG. In the thirteenth embodiment of the present invention, the IEEE 1394 DTCP technology is applied to IrDA (Infrared Data Association), and the D1394 technology is used between an IEEE 1394 device connected to the IEEE 1394 bus and a device that communicates with IrDA. It is characterized by sending and receiving copyright information to each other.

  In order to achieve this object, when the copyright information is transmitted from the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6 bus as shown in FIG. Then, the IEEE packet transferred from the IEEE 1394 device 5 is inserted into the data portion of the data packet that can be transferred by IrDA. Further, the format conversion adapter 35 inserts “Destination ID” which is an identifier of the device into this data packet.

  When data is transferred from the device 37 that communicates with IrDA to the IEEE1394 device 5 connected to the IEEE1394 cable 6, the IrDA compatible device 37 generates data to be inserted into the data area of the data packet in the IEEE1394 packet format. To do. In addition, an identifier “Destination ID” for identifying a destination device is incorporated in the data packet. The data formed in such a format is transferred to the format conversion adapter 35, where the data generated in the IEEE 1394 format is taken out from the data area of the data packet and transmitted to the IEEE 1394 equipment side.

  In this way, it is possible to apply DTCP between an IEEE 1394 device connected to the IEEE 1394 bus and a device that communicates with IrDA, and transmission / reception is performed between the IEEE 1394 device and the IrDA compatible communication device. Unauthorized copying of information can be prevented.

  In addition, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and an IrDA compatible communication device, the existing DTCP standardized by the IEEE 1394 can be applied on the IrDA side, thereby providing an interface. Since it is not necessary to apply a different technology for preventing unauthorized copying every time, it is possible to reduce the cost for constructing a system for transmitting and receiving copyright information.

  Next, a fourteenth embodiment according to the present invention will be described. The fourteenth embodiment according to the present invention is characterized in that an illegal copy protection bit indicating a CCI or key change timing and a “Destination ID” defined in the above-described embodiment are newly defined in an IrDA data packet. Yes. As a result, the illegal copy protection technology of IEEE1394 can be applied to IrDA data packets.

  Next, a fifteenth embodiment according to the present invention will be described with reference to FIG. In the fifteenth embodiment of the present invention, IEEE 1394 DTCP technology is applied to BLUETOOTH, and copyright information is transferred between IEEE 1394 devices connected to the IEEE 1394 bus and devices communicating with BLUETOOTH using the DTCP technology. It is characterized by mutual transmission and reception.

  In order to achieve this object, when the copyright information is transmitted from the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6 to the device 40 that performs communication by BLUETOOTH as shown in FIG. The IEEE packet transferred from the IEEE 1394 device 5 is inserted into the data portion of a data packet that can be transferred by BLUETOOTH. Further, the format conversion adapter 38 inserts “Destination ID” which is an identifier of the device into this data packet.

  In addition, when data is transferred from the device 40 communicating with BLUETOOTH to the IEEE 1394 equipment 5 connected to the IEEE 1394 cable 6, the device 40 generates data to be inserted into the data area of the data packet in the IEEE 1394 packet format. . In addition, an identifier “Destination ID” for identifying a destination device is incorporated in the data packet. The data formed in such a format is transferred to the format conversion adapter 38, where data generated in the IEEE 1394 format is taken out from the data area of the data packet and transmitted to the IEEE 1394 equipment 5 side.

  In this way, it is possible to apply DTCP between an IEEE 1394 device connected to the IEEE 1394 bus and a device that performs communication using BLUETOOTH, and transmission / reception is performed between the IEEE 1394 device and a BLUETOOTH compatible communication device. Unauthorized copying of information can be prevented.

  In addition, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a BLUETOOTH compatible communication device, the existing DTCP standardized by IEEE 1394 can be applied to the BLUETOOTH side, thereby making the interface Since it is not necessary to apply a different technology for preventing unauthorized copying every time, it is possible to reduce the cost for constructing a system for transmitting and receiving copyright information.

  Next, a sixteenth embodiment according to the present invention will be described. The sixteenth embodiment according to the present invention is characterized in that an illegal copy protection bit indicating a CCI or key change timing and a “Destination ID” defined in the above-described embodiment are newly defined in a BLUETOOTH data packet. . As a result, the IEEE1394 illegal copy protection technology can be applied even to a BLUETOOTH data packet.

  Next, a seventeenth embodiment according to the present invention will be described. The seventeenth embodiment according to the present invention is an IEEE 1394 device on the IEEE 1394 bus, and a device connected by a bus or interface (USB, PCI, PCMCIA, IrDA, SCSI, C bus, BLUETOOTH) different from the IEEE 1394 bus. In order to apply DTCP between and transfer copyright information, the packet format of USB, PCI, PCMCIA, IrDA, SCSI, C bus, and BLUETOOTH are all the same as the IEEE 1394 packet format. It is said. The IEEE 1394 packet format is as described in detail in the first embodiment. Therefore, there is no need to newly define a bit indicating CCI, a bit indicating key change timing, or the like, which is a problem when applying DTCP.

  The above-described embodiment is a preferred embodiment of the present invention. However, the present invention is not limited to this, and various modifications can be made without departing from the scope of the present invention. For example, the technology for providing the above-described IEEE1394 illegal copy prevention technology to other buses can be implemented as long as it is based on a serial interface standard such as RS-232C.

  As will be apparent from the above description, the present invention provides an IEEE 1394 format transferred from an IEEE 1394 device when data is transmitted from the IEEE 1394 device connected to the IEEE 1394 bus to a communication device connected to a bus other than the IEEE 1394 bus. The packet and identification information for identifying the communication device defined for each communication device are inserted into a packet in a format corresponding to a bus other than the IEEE 1394 bus, transferred to the communication device side, and the communication device transmits IEEE 1394. When transmitting data to a device, an IEEE 1394 format packet is extracted from a packet corresponding to a bus other than the IEEE 1394 bus into which the IEEE 1394 format packet and identification information are inserted, which is generated in the communication device. On the side By feeding, it becomes possible to also use the bus other than the IEEE1394 bus illegal copy prevention technology IEEE1394, it is possible to transmit and receive the copyright information between the communication device and the IEEE1394 device.

  Furthermore, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a communication device connected to a bus other than the IEEE 1394 bus, the existing illegal copy prevention technology standardized by IEEE 1394 can be applied. As a result, it is not necessary to apply a technology for preventing unauthorized copying that differs for each interface, so that the cost for constructing a system for transmitting and receiving copyright information can be reduced.

  In addition, when transferring data from an IEEE 1394 device connected to the IEEE 1394 bus to a wireless device that performs wireless communication, the IEEE 1394 format packet transferred from the IEEE 1394 device and the wireless device defined for each wireless device are displayed. The identification information for identification is inserted into a packet in a format compatible with wireless communication, transferred to the wireless device side, and generated when the data is transferred from the wireless device to the IEEE 1394 equipment. The IEEE 1394 format packet is taken out of the packet in the format corresponding to the wireless communication into which the IEEE 1394 format packet and the identification information are inserted, and transferred to the IEEE 1394 equipment side, so that the unauthorized copy prevention technology of the IEEE 1394 is used in the wireless communication. Also apply Doo is possible, it is possible to transmit and receive the copyright information between the IEEE1394 device and the wireless device.

  Furthermore, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a wireless device that communicates wirelessly, the existing illegal copy prevention technology standardized by IEEE 1394 can be applied. Thus, it is not necessary to apply different illegal copy prevention techniques for each interface, and thus the cost for constructing a system for transmitting and receiving copyright information can be reduced.

  In addition, in a wireless device connected to a bus other than the IEEE 1394 bus that transmits and receives data to and from an IEEE 1394 device connected to the IEEE 1394 bus, the copy control information in which the allowable number of copies of transfer data is set, and the data are transmitted and received A packet including information indicating the change timing of the encryption key used for the authentication and identification information for identifying the wireless device defined for each wireless device connected to a bus other than the IEEE 1394 bus, and generating IEEE 1394 By transferring data to the device, the unauthorized copy prevention technology of IEEE 1394 can be used in a bus other than the IEEE 1394 bus, and copyright information can be transmitted and received between the IEEE 1394 device and the wireless device. Become.

  Furthermore, in order to send and receive copyright information between IEEE 1394 equipment connected to the IEEE 1394 bus and wireless devices connected to buses other than the IEEE 1394 bus, the existing illegal copy prevention technology standardized by IEEE 1394 can be applied. As a result, it is not necessary to apply a technology for preventing unauthorized copying that differs for each interface, so that the cost for constructing a system for transmitting and receiving copyright information can be reduced.

  In addition, in a communication device connected to a bus other than the IEEE 1394 bus that transmits / receives data to / from an IEEE 1394 device connected to the IEEE 1394 bus, a packet is generated in the IEEE 1394 packet format when the data is transferred to the IEEE 1394 device. Thus, the illegal copy prevention technology of IEEE 1394 can be used in buses other than the IEEE 1394 bus, and copyright information can be transmitted and received between the IEEE 1394 equipment and the communication device.

  Furthermore, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a communication device connected to a bus other than the IEEE 1394 bus, the existing illegal copy prevention technology standardized by IEEE 1394 can be applied. As a result, it is not necessary to apply a technology for preventing unauthorized copying that differs for each interface, so that the cost for constructing a system for transmitting and receiving copyright information can be reduced.

  Also, in a wireless device that wirelessly transmits and receives data to and from an IEEE 1394 device connected to the IEEE 1394 bus, copy control information in which the permitted number of copies of transfer data is set, and an encryption key used to encrypt and transmit the data IEEE 1394 illegal copy prevention technology is wirelessly generated by generating a packet including information indicating the change timing and identification information defined for each device to identify the device and transferring the data to the IEEE 1394 equipment. The present invention can also be applied to communication, and copyright information can be transmitted and received between the IEEE 1394 equipment and the wireless device.

  Furthermore, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a wireless device that communicates wirelessly, the existing illegal copy prevention technology standardized by IEEE 1394 can be applied. Thus, it is not necessary to apply different illegal copy prevention techniques for each interface, and thus the cost for constructing a system for transmitting and receiving copyright information can be reduced.

  In addition, in a wireless device that wirelessly transmits and receives data to and from an IEEE 1394 device connected to the IEEE 1394 bus, when the data is transferred to the IEEE 1394 device, a packet is generated in the IEEE 1394 packet format, thereby preventing unauthorized copying of IEEE 1394. The technology can also be applied to wireless communication, and copyright information can be transmitted and received between the IEEE 1394 equipment and the wireless device.

  Furthermore, in order to send and receive copyright information between an IEEE 1394 device connected to the IEEE 1394 bus and a wireless device that communicates wirelessly, the existing illegal copy prevention technology standardized by IEEE 1394 can be applied. Thus, it is not necessary to apply different illegal copy prevention techniques for each interface, and thus the cost for constructing a system for transmitting and receiving copyright information can be reduced.

It is a block diagram showing the structure of 1st Embodiment which concerns on this invention. It is a block diagram showing the structure of 1st Embodiment which concerns on this invention. It is a figure showing the packet format of the isochronous transfer used for data transfer by IEEE1394. It is a figure showing the packet format of asynchronous transfer used for authentication by IEEE1394. It is a figure showing the packet format of USB. It is a figure showing the packet format of USB in 1st Embodiment. It is a figure showing the packet format of USB in 2nd Embodiment. It is a block diagram showing the structure of 3rd Embodiment based on this invention. It is a block diagram showing the structure of 5th Embodiment concerning this invention. It is a block diagram showing the structure of the 7th Embodiment concerning this invention. It is a block diagram showing the structure of 9th Embodiment based on this invention. It is a block diagram showing the structure of 11th Embodiment based on this invention. It is a block diagram showing the structure of 13th Embodiment based on this invention. It is a block diagram showing the structure of 15th Embodiment based on this invention. It is a block diagram showing the structure of the conventional data transfer system. It is a figure for demonstrating the authentication for encrypting and transmitting data with a transmitter and a receiver.

Explanation of symbols

1 PC
2 PCI bus 3 IEEE 1394 adapter 4 USB adapter 5 IEEE 1394 equipment 6 IEEE 1394 cable 7 USB equipment 8 USB cable

Claims (4)

And IEEE1394 device connected to the IEEE1394 bus, a format conversion apparatus between devices, wherein transmitting and receiving data connected to the bus other than the IEEE1394 bus with the IEEE1394 device,
The format conversion apparatus applies the IEEE 1394 packet format transmitted from the IEEE 1394 equipment to a data area of a data packet of a format corresponding to a bus other than the IEEE 1394 bus of the device, and defines the device defined for each device. format conversion apparatus characterized by incorporating identification information for identifying the. And IEEE1394 device connected to the IEEE1394 bus, a format conversion method in the format converter between devices connected to said bus other than the IEEE1394 bus for transmitting and receiving data with the IEEE1394 device,
The format conversion apparatus applies an IEEE 1394 format packet format transmitted from the IEEE 1394 equipment to a data area of a data packet in a format corresponding to a bus other than the IEEE 1394 bus of the device, and defines the format defined for each device. A format conversion method comprising incorporating identification information for identifying a device. And IEEE1394 device connected to the IEEE1394 bus, the IEEE1394 device with format conversion program and computer readable recording medium in the format conversion device among devices connected to the bus other than the IEEE1394 bus for transmitting and receiving data Because
The format conversion apparatus applies the IEEE 1394 packet format transmitted from the IEEE 1394 equipment to a data area of a data packet of a format corresponding to a bus other than the IEEE 1394 bus of the device, and defines the device defined for each device. The computer-readable recording medium which recorded the format conversion program characterized by incorporating the identification information for identifying ID And IEEE1394 device connected to the IEEE1394 bus, the A format conversion system between devices connected to said bus other than the IEEE1394 bus for transmitting and receiving data with the IEEE1394 device,
The format conversion system applies an IEEE 1394 packet format transmitted from the IEEE 1394 equipment to a data area of a data packet in a format corresponding to a bus other than the IEEE 1394 bus of the device, and defines the device defined for each device. A format conversion system characterized by incorporating identification information for identifying

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