JP4172014B2 - Connection establishment method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention allows a controller-side device connected by a serial bus compliant with the IEEE 1394 standard (hereinafter referred to as an IEEE 1394 serial bus) to transfer data from a controller-side device to a target-side device having a plurality of subunits. The present invention relates to a connection establishment method for forwarding.
[0002]
[Prior art]
In general, when a data sending device serving as a controller transmits data such as a stream to a target device on a network in which a plurality of AV (Audio Visual) devices are connected by an IEEE 1394 serial bus, between each plug After the connection is established, data transmission can be executed by transmitting a control command called AV / C (Audio Video Control) command.
[0003]
FIG. 5 is an example of a conventional model diagram showing a connection establishment process between an IRD having a tuner subunit and a multi-function peripheral having a plurality of tape recorder / player subunits. As shown in FIG. 5, a composite comprising an IRD (Information Resource Dictionary) 1 having a tuner subunit 2 and a plurality of tape recorder / player subunits (hereinafter abbreviated as tape subunits) 4a and 4b. The machine 3 is connected to the IEEE 1394 serial bus 5. The IRD 1 has a function as a controller capable of controlling the tape subunits 4a and 4b with AV / C commands. The multi-function device 3 includes a plurality of output plugs 14 and 15 and input plugs 16 and 17. The tuner subunit 2 on the IRD 1 side includes a source plug 6 and a destination plug. A plug (Destination Plug) 7 is provided.
[0004]
FIG. 7 is a flowchart showing the flow of processing when stream data is simultaneously transmitted from the IRD to a plurality of tape subunits of the multifunction peripheral in the conventional model diagram shown in FIG. With reference to the model diagram of FIG. 5 and the flowchart of FIG. 7, the flow of connection processing when stream data is simultaneously transmitted from the IRD 1 to each of the tape subunits 4 a and 4 b of the multifunction machine 3 for recording will be described. First, the controller of the IRD 1 acquires the isochronous channel (Isochronous Channel) 18 and the band, that is, the network resource of the IEEE 1394 serial bus 5 from the isochronous resource manager, and the IRD 1 as shown by an arrow A in FIG. A point-to-point connection is established from the output plug 8 to the input plug 16 of the multifunction machine 3 (step S21).
[0005]
Next, as indicated by arrow B, the controller of the IRD 1 internally connects the transmission source plug 6 of the tuner subunit 2 in the IRD 1 and the output plug 8 of the unit of the IRD 1 (step S22). Further, the controller of the IRD 1 uses the connection command of the AV / C command as shown by the arrow C to connect the input plug 16 of the multifunction machine 3 and the destination plug 11 of the tape subunit 4a (step S23).
[0006]
Further, as indicated by an arrow D, the controller of the IRD 1 performs a two-point connection by overlay from the output plug 8 of the IRD 1 to the input plug 17 of the multifunction machine 3 (step S24). Note that the connection between the two points by overlay is performed in order to speed up the information processing. Further, as indicated by the arrow E, the controller of the IRD 1 uses the connection command of the AV / C command to connect the input plug 17 of the multifunction device 3 and the destination plug 13 of the tape subunit 4b (step S25).
[0007]
After the connection is completed in such a procedure, the controller of the IRD 1 transmits an AV / C command recording command to the tape subunit 4a and the tape subunit 4b of the multifunction machine 3 (step S26). Two transmission paths are established from the IRD 1 to the multi-function device 3 by the 6-step connection procedure as described above, and stream data is simultaneously transmitted from the IRD 1 to the tape subunit 4a and the tape subunit 4b of the multi-function device 3. can do.
[0008]
Next, a case will be described in which stream data is transmitted and recorded from the IRD 1 to the tape subunit 4a of the multifunction machine 3, and then the stream data is switched to the tape subunit 4b to transmit and record. FIG. 6 is a model diagram of another conventional example showing a connection establishment process between an IRD having a tuner subunit and a multi-function peripheral having a plurality of tape subunits.
6 are the same as those in FIG. 5, the description thereof will be omitted.
[0009]
FIG. 8 is a flowchart showing the flow of processing when stream data is switched and transmitted from the IRD to a plurality of tape subunits of the multifunction peripheral in the conventional model diagram shown in FIG. Connection in the case where the stream data transmitted from the IRD 1 is switched from the tape subunit 4a to the tape subunit 4b of the multi-function apparatus 3 for transmission and recording using the model diagram of FIG. 6 and the flowchart of FIG. The flow of processing will be described. First, the controller of the IRD 1 acquires the isochronous channel 18 and the band, and establishes a point-to-point connection from the output plug 8 of the IRD 1 to the input plug 16 of the multifunction device 3 as indicated by an arrow A in FIG. (Step S31).
[0010]
Next, as indicated by the arrow B, the controller of the IRD 1 internally connects the transmission source plug 6 of the tuner subunit 2 in the IRD 1 and the output plug 8 of the unit of the IRD 1 (step S32). Further, the controller of the IRD 1 uses the connection command of the AV / C command as shown by the arrow C to connect the input plug 16 of the unit of the multifunction machine 3 and the destination plug 11 of the tape subunit 4a (step S33). ). Thereafter, the controller of the IRD 1 transmits an AV / C command recording command to the tape subunit 4a of the multifunction machine 3 (step S34).
[0011]
Further, in order to switch the transmission destination of the stream data, the controller of the IRD 1 transmits a WIND command whose subfunction is “STOP” to the multifunction device 3 so as to stop the tape subunit 4a of the multifunction device 3 (step S35). ).
[0012]
Thereafter, the controller of the IRD 1 sends a disconnection command of the AV / C command to the tape subunit 4a of the multifunction machine 3, and disconnects the connection connected as indicated by the arrow C (step S36). Further, the controller of the IRD 1 disconnects the connection between the two points connected as indicated by the arrow A, releases the isochronous channel 18 from which the network resource has been acquired first (step S37), The internal connection between the transmission source plug 6 and the output plug 8 thus connected is disconnected (step S38).
[0013]
Next, the controller of the IRD 1 acquires the isochronous channel 18 and the band again in order to transmit the stream data to the tape subunit 4b of the multifunction machine 3, and the output plug 8 of the IRD 1 as indicated by the arrow A. To establish a point-to-point connection to the input plug 16 of the multifunction machine 3 (step S39). Further, as indicated by arrow B, the controller of the IRD 1 internally connects the transmission source plug 6 of the tuner subunit 2 in the IRD 1 and the output plug 8 of the unit of the IRD 1 (step S40).
[0014]
Thereafter, the controller of the IRD 1 uses the connection command of the AV / C command as shown by the arrow D to connect the input plug 16 of the unit of the multifunction device 3 and the destination plug 13 of the tape subunit 4b of the multifunction device 3 ( Step S41). Then, the controller of the IRD 1 transmits an AV / C command recording command to the tape subunit 4b of the multifunction machine 3 (step S42). Through the 12-step connection procedure as described above, the transmission path from the IRD 1 to the multifunction device 3 is switched, and the tape subunit 4b of the multifunction device 3 receives the stream data taken over from the tape subunit 4a and continues. You can record.
[0015]
[Problems to be solved by the invention]
However, at present, on the IEEE 1394 serial bus 5, for each tape subunit 4a, 4b of the target device (ie, multifunction device 3) having a plurality of subunits from the controller device (ie, IRD1). The connection establishment method for transmitting various data such as stream data is not defined. Therefore, when simultaneously transmitting stream data or switching transmission destinations from the controller-side device (IRD1) to the plurality of tape subunits 4a, 4b on the multifunction machine 3 side, as in the prior art described above. In addition, it is necessary to complete the establishment of the plug connection through a considerable number of operating procedures. For this reason, there is a possibility that the reliability of the plug connection when establishing the transmission path is lowered. In the future, there will be an increasing demand for processing of target devices that have multiple sub-units in one unit, and transmitting data by operating each sub-unit at the same time or switching operation with a few operating procedures. However, current technology has not yet developed a method for establishing a connection that satisfies such requirements.
[0016]
The present invention has been made in view of such circumstances, and the data transmission device on the controller side, which is the data transmission source, sends data to the target device having a plurality of subunits on the target side. It is an object of the present invention to provide a connection establishment method capable of efficiently establishing a route for transmission.
[0017]
[Means for Solving the Problems]
In order to achieve the above object, a connection establishment method according to claim 1 of the present application is directed to each subunit of a target device having a plurality of subunits from a data transmission device connected to a serial bus compliant with the IEEE1394 standard. When data is transmitted simultaneously, a point-to-point connection is established with one line from the output plug of the data transmission device to the input plug of the target device, and the transmission source plug of the subunit included in the data transmission device And output plug are connected internally. Further, a transmission path is established by connecting one input plug of the target device and a destination plug of each subunit included in the target device by a connection command from the data transmission device. As a result, a predetermined packet can be transmitted from the data transmission device to a plurality of subunits of the target device. In other words, a plurality of transmission paths can be established with fewer connection procedures than the conventional connection establishment method, and various data such as stream data can be simultaneously transmitted and recorded from a data transmission device to a plurality of subunits of a target device. .
[0018]
That is, according to claim 1 of the present application, a plug connection procedure for simultaneously transmitting data from a data sending device connected to a serial bus compliant with the IEEE 1394 standard to a plurality of subunits of the target device is determined. A connection establishment method for establishing a point-to-point connection from an output plug of the data transmission device to an input plug of the target device, a transmission source plug of a subunit included in the data transmission device, and the Based on a procedure for internally connecting the output plug of the data transmission device and a connection command transmitted from the data transmission device, the input plug of the target device and the destination plug of each of the plurality of subunits of the target device Provides a connection establishment method with a procedure to establish a transmission path by connecting It is.
[0021]
In addition, the claims of this application 2 According to the method for establishing a connection, first, for each subunit of a target device having a plurality of subunits from a data transmission device connected to a serial bus conforming to the IEEE 1394 standard, data is first transferred to a certain subunit in the target device. Then, when switching to another subunit and transmitting data, first establish a point-to-point connection with one line from the output plug of the data sending device to the input plug of the target device, The transmission source plug and output plug of the subunit included in the data transmission device are internally connected. Further, based on the connection command sent from the data sending device, the input plug of the target device is connected to the destination plug of the subunit in the target device to be sent first. Next, when switching the data transmission destination to another subunit in the target device, the data transmission device transmits the data without disconnecting the point-to-point connection from the output plug of the data transmission device to the input plug of the target device. Based on the disconnected command and connection command, only the internal connection between the plurality of subunits in the target device is switched to change the transmission path. As a result, the transmission path can be switched with fewer connection procedures than the conventional connection establishment method, and data can be continuously transmitted from the subunit in the target device that was initially connected to another subunit for recording. it can.
[0022]
That is, the claims of this application 2 According to the above, a connection for determining a plug connection procedure when data is alternately switched and transmitted to each of a plurality of subunits of a target device from a data transmission device connected to a serial bus compliant with the IEEE 1394 standard. A method for establishing a point-to-point connection from an output plug of the data transmission device to an input plug of the target device, a transmission source plug of a subunit included in the data transmission device, and the data transmission Based on a procedure for internally connecting the output plug of the device and a connection command sent from the data sending device, the input plug of the target device and a destination plug of a predetermined subunit included in the target device Based on the connection procedure and the connection command sent from the data sending device. And included in the target device based on a procedure for maintaining a two-point connection between the output plug of the data sending device and the input plug of the target device and a disconnect command sent from the data sending device. And a procedure for establishing a transmission path by switching an internal connection from the predetermined subunit to another subunit included in the target device.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of a connection establishment method in the present invention will be described in detail with reference to the drawings. The connection establishment method in the present invention is such that data is transmitted simultaneously from a controller side device connected to an IEEE1394 serial bus to each subunit of a target device having a plurality of subunits, or from one subunit to the other sub-unit. When switching to a unit and transmitting data, the establishment of a connection is completed with a small operation procedure, and a highly reliable transmission path is established.
[0024]
FIG. 1 is a model diagram showing a connection establishment process between an IRD including a tuner subunit and a multi-function peripheral including a plurality of tape subunits in the embodiment of the present invention. FIG. 2 is a module configuration diagram of a controller-side device and a target-side device in the embodiment of the present invention. That is, in FIG. 2, the module configuration of the IRD 1 in FIG. 1 is shown as the device on the controller side, and the module configuration of the MFP 3 in FIG. 1 is shown as the device on the target side.
[0025]
First, the configuration of a connection device for realizing the plug connection establishment method according to the present invention will be described. As shown in FIG. 1, an IRD 1 that is a controller-side device and a multifunction device 3 that is a target-side device are connected to an IEEE 1394 serial bus 5. That is, the IRD 1 having the tuner subunit 2 and the multi-function device 3 having the plurality of tape subunits 4 a and 4 b are connected to an isochronous channel (isochronous channel) 18 on the IEEE 1394 serial bus 5. The IRD 1 has a function as a controller that can control the tape subunits 4a and 4b of the multifunction machine 3 using AV / C commands.
[0026]
The unit of the multifunction device 3 includes output plugs 14 and 15 and input plugs 16 and 17, the tape subunit 4a includes the transmission source plug 10 and the destination plug 11, and the tape subunit 4b includes the transmission source plug 12. And a destination plug 13. Further, the IRD 1 unit includes an output plug 8 and an input plug 9, and the tuner subunit 2 includes a transmission source plug 6 and a destination plug 7.
[0027]
In FIG. 2, an IRD 1 as a controller-side device is a GUI (Graphical User Interface) management module 21 serving as an interface for visually operating a computer and an IRD for starting application software for operating the IRD 1 controller. An IRD side middleware control module 23 for controlling the application software of the IRD 1, an IRD side isochronous channel connection module 24 for connecting the IRD 1 to the isochronous channel 18 of the IEEE 1394 serial bus 5, and The AV / C controller module 25 that generates an AV / C command for the IRD1 controller to control the tape subunits 4a and 4b of the multi-function device 3, and accurate bit transmission on the data communication line on the IRD1 side It is constituted by the IRD side IEEE1394 lower layer module 26 to provide such Utame physical layer.
[0028]
Further, the multifunction device 3 as the target device includes a multifunction device side application 31 for starting up the application software of the tape subunits 4a and 4b and a multifunction device side middleware for controlling the application software of the multifunction device 3. The control module 32, the MFP-side isochronous channel connection module 33 for connecting the MFP 3 to the isochronous channel 18 of the IEEE1394 serial bus 5, and the AV / C command received from the controller of the IRD 1 A multi-function device side IEEE 1394 that provides an AV / C target module 34 for transmission to the corresponding tape subunit 4a, 4b and a physical layer for performing accurate bit transmission on the data communication line on the multi-function device 3 side. And a lower layer module 35.
[0029]
Next, the flow of processing for establishing a connection in the present invention will be described. FIG. 3 is a flowchart showing the flow of processing when stream data is simultaneously transmitted from the IRD 1 to the plurality of tape subunits 4a and 4b of the multifunction machine 3 in the model diagram of the present invention shown in FIG. Hereinafter, the connection establishment process of the present invention in the case where stream data is simultaneously transmitted and recorded from the IRD 1 side to the plurality of tape subunits 4a and 4b on the multifunction device 3 side with reference to FIG. 1, FIG. 2 and FIG. The flow of will be described.
[0030]
First, when the IRD 1 is started, the controller of the IRD 1 starts up the IRD side application 22 and then controls the application software by the IRD side middleware control module 23 using the GUI management module 21 and the IRD side isochronous. The channel connection module 24 is activated. At the same time, the AV / C controller module 25 and the IRD side IEEE 1394 lower layer module 26 are also started up. In addition, the MFP-side application 31 of the MFP 3 that is the target-side device, the MFP-side middleware control module 32, the MFP-side isochronous channel connection module 33, the AV / C target module 34, and the MFP-side IEEE 1394 subordinate The layer module 35 also stands up at the same time.
[0031]
As a result, the controller of the IRD 1 operates the IRD side isochronous channel connection module 24 and the multifunction device side isochronous channel connection module 33 to acquire the isochronous channel 18 and the bandwidth from the IEEE 1394 serial bus 5. As shown by the arrow A in FIG. 1, a point-to-point connection is established from the output plug 8 of the IRD 1 to the input plug 16 of the unit of the multifunction machine 3 (step S1). Further, as indicated by an arrow B, the controller of the IRD 1 internally connects the transmission source plug 6 of the tuner subunit 2 in the IRD 1 and the output plug 8 of the unit of the IRD 1 (step S2). Further, the controller of the IRD 1 uses the connection command of the AV / C command generated by the AV / C controller module 25 of the IRD 1 as indicated by the arrow C, and the input plug 16 and the tape subunit of the unit of the multifunction device 3. The destination plug 11 of 4a is connected (step S3).
[0032]
Next, the controller of the IRD 1 uses the connection command of the AV / C command generated by the AV / C controller module 25 of the IRD 1 as shown by the arrow D, and the input plug 16 and the tape sub of the unit of the multifunction device 3. The destination plug 13 of the unit 4b is connected (step S4). Further, the controller of the IRD 1 transmits an AV / C command recording command to the tape subunit 4a and the tape subunit 4b of the multifunction machine 3 (step S5).
[0033]
It should be noted that the controller of the IRD 1 does not transmit the AV / C command recording command to the tape subunits 4a and 4b simultaneously as indicated by the arrows C and D, but instead of the AV / C command connection command as indicated by the arrow E. May be used to connect the source plug 10 of the tape subunit 4a and the destination plug 13 of the tape subunit 4b, and transmit the AV / C command recording command from the tape subunit 4a to the tape subunit 4b. .
[0034]
Two transmission paths are established by the above five-step connection procedure, and stream data can be simultaneously transmitted from the IRD 1 to the tape subunits 4a and 4b of the multifunction machine 3 for recording. As described above, according to the connection establishment procedure of the present invention shown in FIG. 3, the transmission path can be established with an operation procedure one step fewer than the conventional connection establishment procedure as shown in FIG.
[0035]
Next, the flow of processing when the stream data is transmitted from the IRD 1 to the tape subunit 4a of the multifunction machine 3 for recording and then switched to the tape subunit 4b for transmission and recording will be described. FIG. 4 is a flowchart showing the flow of processing when stream data is switched and transmitted from the IRD 1 to a plurality of tape subunits of the multifunction device 3 in the model diagram of the present invention shown in FIG. The flow of processing when stream data is switched and recorded from the IRD 1 side to the plurality of tape subunits 4a and 4b on the multifunction device 3 side will be described with reference to FIGS.
[0036]
First, the controller of the IRD 1 obtains the isochronous channel 18 and the band from the IEEE 1394 serial bus 5 and, as indicated by the arrow A in FIG. 1, two points from the output plug 8 of the IRD 1 to the input plug 16 of the multifunction machine 3. An inter-connection is established (step S11). Next, the controller of the IRD 1 internally connects the transmission source plug 6 of the tuner subunit 2 in the IRD 1 and the output plug 8 of the unit of the IRD 1 as indicated by the arrow B (step S12). Further, the controller of the IRD 1 uses the connection command of the AV / C command generated by the AV / C controller module 25 as indicated by the arrow C, and uses the connection plug 16 of the unit of the multifunction device 3 and the tape subunit 4a. The destination plug 11 is connected (step S13).
[0037]
Thereafter, the controller of the IRD 1 sends an AV / C command recording command to the tape subunit 4a of the multifunction machine 3 (step S14). Further, in order to switch the recording destination of the stream data, the controller of the IRD 1 transmits a WIND command whose subfunction is “STOP” to the multi function device 3 in order to stop the tape subunit 4a (step S15). Then, the controller of the IRD 1 transmits an AV / C command disconnection command to the tape subunit 4a to disconnect the connection indicated by the arrow C in FIG. 1 (step S16).
[0038]
Further, as indicated by an arrow D, the controller of the IRD 1 uses the connection command of the AV / C command to connect the input plug 16 of the unit of the multifunction machine 3 and the destination plug 13 of the tape subunit 4b (step S17). ). Thereafter, the controller of the IRD 1 transmits an AV / C command recording command to the tape subunit 4b (step S18). The transmission path is switched by the above-described 8-step connection procedure, and stream data is subsequently transmitted from the tape subunit 4a to the tape subunit 4b, so that recording can be continued. As described above, according to the connection establishment procedure of the present invention shown in FIG. 4, the transmission path can be established by an operation procedure having four steps less than the conventional connection establishment procedure as shown in FIG.
[0039]
In the case of the plug connection establishment method according to the present invention, the resources reserved for establishing the transmission path to the tape subunit 4a of the multifunction machine 3 are not released, and the resources are directly transferred to the tape subunit 4b. Can be used for establishment. Therefore, compared to the conventional connection establishment method, there is no need to re-acquire resources when switching the transmission path from the tape subunit 4a to the tape subunit 4b, so that there is no risk of failure in establishing the transmission path. Therefore, compared with the conventional connection establishment method, the processing for establishing the transmission path requires less processing, so that a highly reliable transmission path can be established and the transmission path can be established reliably in a short time. be able to.
[0040]
The embodiment described above is an example for explaining the present invention, and the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the gist of the invention. For example, in the connection establishment method of the above embodiment, an example of plug connection between an IRD and a multifunction device having two tape subunits has been given, but there are three or more tape subunits in the multifunction device. However, it goes without saying that the connection establishment method of the above embodiment is applied. Further, it goes without saying that the present invention is applied even if the multi-function device includes a disk subunit instead of the tape subunit. Note that in the connection establishment method of the present invention, any transmission method may be used as the transmission method of the stream data.
[0041]
By the way, as is apparent from the plug connection establishment method described in the above embodiment, after establishing a transmission path in the present invention, a procedure for transmitting a predetermined packet from the data sending device to a plurality of subunits of the target device. It is a preferable aspect of the present invention to provide a packet transmission method including
[0042]
【The invention's effect】
As described above, according to the connection establishment method of the present invention, the controller side data transmission device connected to the IEEE 1394 serial bus is connected to the plurality of subunits of the target device which is a multi-function device having a plurality of subunits. On the other hand, when various data such as stream data are transmitted simultaneously, the transmission path can be established by a connection processing procedure that is smaller than that of the conventional connection establishment method. Therefore, various data such as stream data can be simultaneously transmitted and recorded from a data transmission device to a plurality of subunits of a target device with a simple operation procedure.
[0043]
Also, according to the connection establishment method of the present invention, a plurality of subunits in the target device can be internally connected to each other, so that a plurality of transmission paths can be established with fewer connection procedures than the conventional connection establishment method. Can do. Therefore, it is possible to establish a highly reliable transmission path and simultaneously transmit and record various data such as stream data to a plurality of subunits of the target device.
[0044]
In addition, according to the connection establishment method of the present invention, when data is transmitted by switching from one subunit of the target device to another subunit, the transmission path can be switched with less connection processing than the conventional connection establishment method. it can. As a result, a highly reliable transmission path can be established, and data can be continuously transmitted from the subunit in the target device connected first to another subunit for recording.
[Brief description of the drawings]
FIG. 1 is a model diagram showing a connection establishment process between an IRD including a tuner subunit and a multi-function peripheral including a plurality of tape subunits according to an embodiment of the present invention.
FIG. 2 is a module configuration diagram of a device on the controller side and a device on the target side in the embodiment of the present invention.
FIG. 3 is a flowchart showing a flow of processing when stream data is simultaneously transmitted from the IRD to a plurality of tape subunits of the multifunction peripheral in the model diagram of the present invention shown in FIG. 1;
4 is a flowchart showing a flow of processing when stream data is switched and transmitted from the IRD to a plurality of tape subunits of the multifunction peripheral in the model diagram of the present invention shown in FIG. 1;
FIG. 5 is an example of a conventional model diagram showing a connection establishment process between an IRD having a tuner subunit and a multi-function peripheral having a plurality of tape subunits.
FIG. 6 is a model diagram of another conventional example showing a process for establishing a connection between an IRD having a tuner subunit and a multi-function peripheral having a plurality of tape subunits.
7 is a flowchart showing a flow of processing when stream data is simultaneously transmitted from the IRD to a plurality of tape subunits of the multifunction peripheral in the conventional model diagram shown in FIG.
8 is a flowchart showing a flow of processing when stream data is switched and transmitted from the IRD to a plurality of tape subunits of the multifunction peripheral in the conventional model diagram shown in FIG. 6;
[Explanation of symbols]
1 IRD (Information Resource Dictionary)
2 Tuner subunit
3 MFP
4a, 4b Tape subunit (tape recorder / player subunit)
5 IEEE1394 serial bus
6, 10, 12 Source Plug
7, 11, 13 Destination Plug
8, 14, 15 Output Plug
9, 16, 17 Input Plug
18 Isochronous Channel (Isochronous Channel)
21 GUI (Graphical User Interface) management module
22 IRD side application
23 IRD side middleware control module
24 IRD side isochronous channel connection module
25 AV / C controller module
26 IRD side IEEE 1394 lower layer module
31 MFP application
32 MFP side middleware control module
33 Multifunction peripheral isochronous channel connection module
34 AV / C target module
35 Multifunction device side IEEE 1394 lower layer module

Claims (2)

A connection establishment method for determining a plug connection procedure for simultaneously transmitting data from a data transmission device connected to a serial bus conforming to the IEEE 1394 standard to a plurality of subunits of a target device,
Establishing a point-to-point connection from the output plug of the data sending device to the input plug of the target device;
A procedure for internally connecting a transmission source plug of a subunit included in the data transmission device and the output plug of the data transmission device;
Based on a connection command sent from the data sending device, a procedure for establishing a transmission path by connecting the input plug of the target device and each destination plug of the plurality of subunits of the target device,
A connection establishment method. This is a connection establishment method for determining a plug connection procedure when data is transmitted by switching alternately from a data transmission device connected to a serial bus compliant with the IEEE 1394 standard to each of a plurality of subunits of a target device. And
Establishing a point-to-point connection from the output plug of the data sending device to the input plug of the target device;
A procedure for internally connecting a transmission source plug of a subunit included in the data transmission device and the output plug of the data transmission device;
A step of connecting the input plug of the target device and a destination plug of a predetermined subunit included in the target device based on a connection command sent from the data sending device;
Maintaining a point-to-point connection between the output plug of the data sending device and the input plug of the target device based on the connection command sent from the data sending device;
A procedure for establishing a transmission path by switching internal connections from the predetermined subunit included in the target device to another subunit included in the target device based on a disconnect command sent from the data sending device; ,
A connection establishment method.

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