JP3891927B2 - Communication equipment and network system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a communication system having an IEEE 1394 serial bus communication function and a network system that shares isochronous resources in a network in which a plurality of communication apparatuses are network-connected by an IEEE 1394 serial bus.
[0002]
[Prior art]
In the conventional technology, according to the IEEE 1394 serial bus standard (see Non-Patent Document 1), an isochronous resource consisting of an isochronous channel and an isochronous band necessary for isochronous transfer is managed by an isochronous resource manager, and isochronous transfer is performed. The communication device to be performed acquired isochronous resources from the isochronous resource manager and then performed isochronous transfer. Since the management of isochronous resources is performed depending on whether it is used or not, communication that performs isochronous transfer at a communication cycle longer than a specific interval generally called an isochronous transfer cycle defined in the IEEE 1394 serial bus standard (see Non-Patent Document 1) The isochronous resource secured by the device may not be used when viewed at the specific interval.
[0003]
[Non-Patent Document 1]
IEEE Std 1394-1995, IEEE Standard for a High Performance Serial Bus
[0004]
FIG. 11 shows a configuration example of a conventional network system.
The communication device A 301 includes 302 IEEE 1394 serial bus communication function units, and the communication device B 303 includes 304 IEEE 1394 serial bus communication function units and 305 defined by the IEEE 1394 serial bus standard (see Non-Patent Document 1). It has an isochronous resource manager function unit and 306 cycle master function units defined by the IEEE 1394 serial bus standard (see Non-Patent Document 1), and 307 communication equipment C has 308 IEEE 1394 serial bus communication function units. I have.
The IEEE 1394 serial bus communication function unit 302, the IEEE 1394 serial bus communication function unit 304, and the IEEE 1394 serial bus communication function unit 308 communicate with other communication devices connected via the IEEE 1394 serial bus via the IEEE 1394 serial bus. Has the function of
It is assumed that the functions of the 305 isochronous resource manager function unit and the cycle master function unit 306 in the communication device B 303 are operating.
According to the IEEE 1394 serial bus standard (see Non-Patent Document 1), a communication device in which the 305 isochronous resource manager function unit operates as an isochronous resource manager manages the isochronous resource, and the 306 cycle master function unit. As a cycle master, a communication device that operates is transmitted a cycle start packet at a specific interval defined by the IEEE 1394 serial bus standard (see Non-Patent Document 1). In addition, a communication device that performs synchronous communication called isochronous transfer performs isochronous resource acquisition processing for acquiring isochronous resources from the isochronous resource manager, acquires the isochronous resources, and then synchronizes with the cycle start packet. To perform isochronous transfer.
It is assumed that 301 communication device A and 303 communication device B are network-connected by 309 IEEE 1394 serial bus A, and 303 communication device B and 307 communication device C are network-connected by 310 IEEE 1394 serial bus B.
311 is an isochronous resource acquisition process A, in which 301 communication apparatus A acquires an isochronous resource from 303 communication apparatus B, which is an isochronous resource manager. 312 isochronous resource acquisition process B In this processing, the communication device C 307 acquires an isochronous resource from the communication device B 303, which is an isochronous resource manager.
[0005]
FIG. 12 shows an example of conventional isochronous transfer.
316 cycle start packet 1 and 317 cycle start packet 2 and 318 cycle start packet 3 and 319 cycle start packet 4 and 320 cycle start packet 5 are the cycle master Is transmitted at a specific interval of 315 defined by the IEEE 1394 serial bus standard (see Non-Patent Document 1).
321 isochronous packet A1 and 322 isochronous packet A2 and 323 isochronous packet A3 are isochronous packets of the same size, and are transferred using isochronous channel A in the communication cycle of 313 isochronous transfer communication cycle A. The 324 isochronous packet B1 and the 325 isochronous packet B2 are isochronous packets of the same size, and are transferred using the isochronous channel B in the communication cycle of 314 isochronous transfer communication cycle B.
Here, the isochronous transfer communication cycle A of 313 is twice the specific interval of 315 defined by the IEEE 1394 serial bus standard (see Non-Patent Document 1), and the isochronous transfer communication cycle B of 314 is twice the specific interval. It is.
[0006]
A conventional network will be described with reference to FIGS.
The communication device B 303 as the cycle master has 316 cycle start packets 1 and 317 cycle start packets 2 and 318 cycle start packets 3 and 319 cycle start Transmit packet 4 and 320 cycle start packet 5.
When the communication device A 301 performs isochronous transfer of the isochronous packet A1 of 321 and the isochronous packet A2 of 322 and the isochronous packet A3 of 323 in the communication cycle of 313, the isochronous resource manager After acquiring an isochronous band sufficient to transfer the isochronous channel A and the isochronous packet A1 in the isochronous resource acquisition processing A of 311 from the communication device B of 313, the isochronous transfer communication period A of 313 is acquired. Using the isochronous channel A, the 321 isochronous packet A1, the 322 isochronous packet A2, and the 323 isochronous packet A3 are acquired using the isochronous channel A. Sokuronasu to transfer.
When the communication device C 307 performs isochronous transfer of the isochronous packet B1 of 324 and the isochronous packet B2 of 325 in the communication cycle of the isochronous transfer communication cycle B of 314, the communication device B of 303 which is an isochronous resource manager. 312 to 312, after obtaining an isochronous band sufficient to transfer the isochronous channel B and the isochronous packet B 1 as isochronous resources in the isochronous resource acquisition processing B 312, the communication cycle of the isochronous transfer communication cycle B 324 Then, the isochronous channel B is used to isochronously transfer the 324 isochronous packet B1 and the 325 isochronous packet B2.
[0007]
[Problems to be solved by the invention]
However, in the conventional isochronous resource acquisition method, an isochronous resource secured by a communication device that performs isochronous transfer with a communication period longer than a specific interval defined in the IEEE 1394 serial bus standard (see Non-Patent Document 1) There is a problem in that isochronous resources are wasted when they are not used every time.
Therefore, the present invention has been made in view of such a problem, and in a system in which a plurality of communication devices are connected to a network by an IEEE 1394 serial bus, sharing isochronous resources and wasteful acquisition of isochronous resources. It is an object of the present invention to provide a network system that can prevent the occurrence of a problem.
[0008]
[Means for Solving the Problems]
  In order to solve the above problems, the invention of the IEEE 1394 communication system according to claim 1 provides:In an IEEE 1394 communication system that includes at least one first communication device and one second communication device and performs communication at a communication cycle that is an integral multiple of the isochronous transfer cycle, the first communication device has its own isochronous device. An isochronous transfer communication cycle transmission function unit that transmits a transfer communication cycle, an isochronous transfer timing reception function unit that receives a timing at which its own communication device performs isochronous transfer, and an isochronous transfer that performs isochronous transfer at the received isochronous transfer timing An isochronous transfer communication cycle transmission function unit that transmits its own isochronous transfer communication cycle and the isochronous transfer communication cycle of itself and the first communication device. Acquisition of isochronous transfer communication cycle Group the self and the first communication device having the same isochronous transfer communication cycle acquired, and acquire communication resources necessary for the group self and the first communication device, A group classification function unit for determining an isochronous transfer timing of itself and the first communication device, an isochronous transfer timing notification function unit for notifying the isochronous transfer timing of the group and the first communication device, and the isochronous transfer The isochronous transfer timing receiving function unit for receiving timing, and the isochronous transfer function unit for executing isochronous transfer at the received isochronous transfer timing.
Accordingly, the communication cycle of the isochronous transfer of the own communication device is transmitted to the other communication device via the IEEE 1394 serial bus, the communication cycle of the isochronous transfer is acquired from the other communication device, and the IEEE 1394 serial bus is not transmitted. The communication cycle of the isochronous transfer of the own communication device can be acquired, and the communication cycle of the isochronous transfer of the own communication device is transmitted to the other communication device via the IEEE1394 serial bus, and the isochronous transfer is transmitted from the other communication device. Thus, isochronous transfer can be performed at the timing of receiving this timing and the timing of the received isochronous transfer.
Further, it is possible to acquire the communication cycle of isochronous transfer from another communication device via the IEEE1394 serial bus, notify the timing of isochronous transfer to the other communication device, and classify the communication device into several groups. In addition, transmitting the isochronous transfer communication cycle of the communication device to another communication device via the IEEE1394 serial bus, receiving the isochronous transfer timing, and performing isochronous transfer at the received isochronous transfer timing. It becomes possible to acquire the communication cycle of isochronous transfer from another communication device, notify the timing of isochronous transfer to the other communication device, and classify the communication device into several groups.
  The invention according to claim 22. The IEEE 1394 communication system according to claim 1, wherein the group classification function unit of the second communication device acquires the isochronous transfer communication cycle from the first communication device and the isochronous transfer communication cycle acquisition function unit. The isochronous transfer timing is determined according to the order within the same group, or the order of the node IDs of the self and the first communication device in the same group.
  As a result, the isochronous transfer timing is determined in the order in which the isochronous transfer communication cycle acquisition function unit acquires the isochronous transfer communication cycle, but in addition, the order of the node IDs assigned to the communication devices by the IEEE 1394 serial bus may be improved. More convenient.
[0009]
  According to a third aspect of the present invention, in the IEEE1394 communication system according to the first or second aspect, any one communication device having an isochronous resource manager function unit becomes an isochronous resource manager, and the group classification function unit is The communication device has a feature that a communication device that performs isochronous transfer collectively obtains isochronous resources necessary for isochronous transfer from the isochronous resource manager. As a result, it is possible to prevent the isochronous resource acquisition process from being performed a plurality of times and to prevent unnecessary acquisition of isochronous resources.
[0010]
  According to a fourth aspect of the present invention, in the IEEE 1394 communication system according to the third aspect, any one communication device having a cycle master function unit is a cycle master, and is more isochronous than a communication device having the group classification function unit. The communication device that performs the transfer is notified of the timing of the isochronous transfer, and the communication device that has received the notification performs the isochronous transfer at the notified timing of the isochronous transfer. As a result, the communication device including the group classification function unit can control the timing of isochronous transfer of the communication device including the isochronous transfer function unit.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
A communication device according to the first embodiment of the present invention will be described with reference to FIG.
The communication device 201 includes a 202 IEEE 1394 serial bus communication function unit and a 203 asynchronous transfer cycle transmission function unit.
The IEEE 1394 serial bus communication function unit 202 has a function for communicating with other communication devices connected to the network via the IEEE 1394 serial bus via the IEEE 1394 serial bus.
In the asynchronous transfer cycle transmission function unit 203, for example, a register representing the communication cycle of isochronous transfer of the own communication device is provided in the configuration ROM employed in the IEEE1394 serial bus (Non-patent Document 1), and the own communication device is provided in the register. The communication cycle of the isochronous transfer is described, and the communication cycle of the isochronous transfer of the own communication device is transmitted to the other communication device by permitting reading from the other communication device connected by the IEEE1394 serial bus.
In the above, a register is provided in the configuration ROM in order to transmit the communication cycle of isochronous transfer of the own communication device. However, the initial register space, initial unit space, private space, or A register may be provided in any one of the initial memory spaces. Further, a parameter may be provided outside the space, and the parameter may be read by writing to a register provided in any one of the spaces.
According to the communication device of this embodiment, the communication function unit of the IEEE 1394 serial bus 202 and the isochronous transfer communication cycle transmission function unit 203 are provided together so that the communication device can communicate with other communication devices via the IEEE 1394 serial bus. It is possible to transmit the communication cycle of isochronous transfer.
[0012]
A communication device according to the second embodiment of the present invention will be described with reference to FIG.
The communication device 204 includes 202 IEEE 1394 serial bus communication function units and 205 isochronous transfer communication cycle acquisition function units.
The isochronous transfer communication cycle acquisition function unit 205 reads, for example, a register representing the communication cycle of the isochronous transfer of the own communication device provided by the 203 isochronous transfer communication cycle transfer function unit of another communication device connected by the IEEE1394 serial bus. The communication cycle of isochronous transfer of the other communication device is acquired.
According to the communication device of this embodiment, 202 IEEE 1394 serial bus communication function unit and 205 isochronous transfer communication cycle acquisition function unit are provided together, so that communication of isochronous transfer of other communication devices via the IEEE 1394 serial bus is possible. There is an effect that the period can be acquired.
[0013]
A communication device according to a third embodiment of the present invention will be described with reference to FIG.
A communication device 206 includes an IEEE 1394 serial bus communication function unit 202, an isochronous transfer communication cycle transmission function unit 203, and an isochronous transfer communication cycle acquisition function unit 205.
According to the communication apparatus of this embodiment, 202 IEEE1394 serial bus communication function unit, 203 isochronous transfer communication cycle transmission function unit, and 205 isochronous transfer communication cycle acquisition function unit are provided in combination. The communication cycle of the isochronous transfer of the own communication device to the other communication device, acquiring the communication cycle of the isochronous transfer from the other communication device, and isochronous transfer of the own communication device without going through the IEEE 1394 serial bus. There is an effect that a communication cycle can be acquired.
[0014]
A communication device according to a fourth embodiment of the present invention will be described with reference to FIG.
The communication device 207 includes an IEEE 1394 serial bus communication function unit 202, an isochronous transfer communication cycle transmission function unit 203, and a 208 isochronous transfer timing reception function unit 203.
In the 208 isochronous transfer timing reception function unit, for example, a register representing the isochronous transfer timing of the communication device is provided in the configuration ROM employed in the IEEE 1394 serial bus (Non-patent Document 1), and is connected via the IEEE 1394 serial bus. By permitting writing from the other communication device, the timing of isochronous transfer of the own communication device is received from the other communication device.
In the above, a register is provided in the configuration ROM in order to receive the isochronous transfer timing of its own communication device, but the initial register space, initial unit space, private space or initial space employed in the IEEE1394 serial bus (Non-patent Document 1) A register may be provided in any one of the memory spaces.
Further, the parameter may be influenced by providing a parameter outside the space and writing it in a register provided in any one of the spaces.
According to the communication apparatus of this embodiment, 202 IEEE 1394 serial bus communication function unit, 203 isochronous transfer communication cycle transmission function unit, and 208 isochronous transfer timing reception function unit are provided together, thereby allowing the communication via the IEEE 1394 serial bus. Thus, there is an effect that the communication cycle of the isochronous transfer of the own communication device can be transmitted to the other communication device and the timing of the isochronous transfer can be received from the other communication device.
[0015]
A communication device according to a fifth embodiment of the present invention will be described with reference to FIG.
The communication device 209 includes an IEEE 1394 serial bus communication function unit 202, an isochronous transfer communication cycle transmission function unit 203, an isochronous transfer timing reception function unit 208, and an isochronous transfer function unit 210 at a reception timing.
In the isochronous transfer function unit at the 210 reception timing, for example, a register value indicating the isochronous transfer timing provided by the 208 isochronous transfer timing reception function unit and, for example, an IEEE 1394 serial bus (Non-patent Document 1) are employed. When the value matches the value of the CYCLE_TIME register, isochronous transfer is performed.
In the above, for example, the register value indicating the isochronous transfer timing of the communication device provided by the isochronous transfer timing reception function unit 208 is compared with the value of the CYCLE_TIME register. However, instead of the CYCLE_TIME register, the IEEE1394 serial bus (non-patent document Regardless of whether the register in the initial register space, initial unit space, private space, or initial memory space adopted in 1), parameters outside the space, or input values from the outside are used, the IEEE 1394 serial bus It may be the number of packets transferred.
The comparison method may be coincidence, above, hereinafter, logical sum, logical product, logical inversion, or a combination thereof.
According to the communication apparatus of this embodiment, 202 is an IEEE 1394 serial bus communication function unit, 203 is an isochronous transfer communication cycle transmission function unit, 208 is an isochronous transfer timing reception function unit, and 210 is an isochronous transfer function unit at reception timing. In addition, the communication cycle of the isochronous transfer of the own communication device is transmitted to the other communication device via the IEEE 1394 serial bus, the timing of the isochronous transfer is received from the other communication device, and the timing of the received isochronous transfer. There is an effect that isochronous transfer can be performed.
[0016]
A communication device according to a sixth embodiment of the present invention will be described with reference to FIG.
The communication device 211 includes an IEEE 1394 serial bus communication function unit 202, an isochronous transfer communication period acquisition function unit 205, and an isochronous transfer timing notification function unit 212.
In the isochronous transfer timing notification function unit 212, the timing of performing isochronous transfer to, for example, a register indicating the isochronous transfer timing of the own communication device provided by the isochronous transfer timing reception function unit 208 of the other communication device connected by the IEEE1394 serial bus. Is written to the other communication device to notify the timing of isochronous transfer.
According to the communication device of this embodiment, 202 IEEE 1394 serial bus communication function unit, 205 isochronous transfer communication period acquisition function unit, and 212 isochronous transfer timing notification function unit are provided together, so that it can be connected via the IEEE 1394 serial bus. Thus, there is an effect that the communication cycle of isochronous transfer can be acquired from another communication device and the timing of isochronous transfer can be notified to the other communication device.
[0017]
A communication device according to a seventh embodiment of the present invention will be described with reference to FIG.
The communication device 213 includes an IEEE 1394 serial bus communication function unit 202, an isochronous transfer communication period acquisition function unit 205, an isochronous transfer timing notification function unit 212, and a group classification function unit 214.
In the group classification function unit 214, first, for example, communication devices having the same communication cycle are collected into one group based on the communication cycle of isochronous transfer of other communication devices acquired by the isochronous transfer communication cycle acquisition function unit 205. .
Next, for each group, it is confirmed whether the communication devices belonging to the group can perform isochronous transfer without interfering with each other. If the isochronous transfer interferes, further grouping is performed so that the isochronous transfer does not interfere.
In the above, communication devices having the same communication cycle are collected and grouped based on the communication cycle of isochronous transfer of other communication devices acquired by the isochronous transfer communication cycle acquisition function unit 205, but a certain value or an average value of the communication cycle , Based on median or mode. The comparison method may be coincidence, above, hereinafter, logical sum, logical product, logical inversion, or a combination thereof.
Further, in the group classification function unit 214, for each classified group, a plurality of communication devices are isochronous in the order in which, for example, the isochronous transfer communication cycle acquisition function unit 205 acquires the isochronous transfer communication cycle, and in the same isochronous transfer period. The timing of isochronous transfer of each communication device is determined so that transfer is not performed.
[0018]
In the above description, the isochronous transfer timing is determined in the order in which the isochronous transfer communication cycle is acquired by the 205 isochronous transfer communication cycle acquisition function unit. However, the order of node IDs assigned to communication devices by the IEEE 1394 serial bus (Non-patent Document 1). However, in the order of register values in any of the initial register space, initial unit space, private space, or initial memory space adopted in the IEEE 1394 serial bus (Non-patent Document 1) The order may be the order of input values from the outside.
According to the communication apparatus of this embodiment, the IEEE 1394 serial bus includes the 202 IEEE 1394 serial bus communication function unit, the 205 isochronous transfer communication period acquisition function unit, the 212 isochronous transfer timing notification function unit, and the 214 group classification function unit. The communication cycle of isochronous transfer is acquired from the other communication device via the communication device, the timing of isochronous transfer is notified to the other communication device, and the communication device can be classified into several groups.
[0019]
A communication device according to an eighth embodiment of the present invention will be described with reference to FIG.
The communication device 215 includes an IEEE1394 serial bus communication function unit 202, an isochronous transfer communication cycle transmission function unit 203, an isochronous transfer communication cycle acquisition function unit 205, an isochronous transfer timing reception function unit 208, and a reception timing 210. An isochronous transfer function unit, a 212 isochronous transfer timing notification function unit, and a 214 group classification function unit are provided.
According to the communication device of this embodiment, 202 is an IEEE 1394 serial bus communication function unit, 203 is an isochronous transfer communication cycle transmission function unit, 205 is an isochronous transfer communication cycle acquisition function unit, and 208 is an isochronous transfer timing reception function unit. By combining the isochronous transfer function unit at the reception timing, the isochronous transfer timing notification function unit 212 and the group classification function unit 214, the communication of isochronous transfer of the own communication device to another communication device via the IEEE1394 serial bus is provided. Communicating the cycle, acquiring the communication cycle of isochronous transfer from another communication device, receiving the timing of isochronous transfer from the other communication device, and performing isochronous transfer at the timing of the received isochronous transfer Notifying other communication devices of the timing of isochronous transfer, classifying the communication devices into several groups, obtaining the communication cycle of the isochronous transfer of the own communication device without going through the IEEE 1394 serial bus, and the own communication There is an effect that the timing of isochronous transfer from the device can be received.
[0020]
FIG. 1 shows a network system according to this embodiment.
The communication apparatus A 101 includes a 102 IEEE 1394 serial bus communication function unit, an isochronous transfer communication cycle transmission function unit 103, an isochronous transfer timing reception function unit 104, and an isochronous transfer function unit 105 at the reception timing. It has the same function as the communication device of the fifth embodiment of the invention.
The communication device B 106 includes a 107 IEEE 1394 serial bus communication function unit, an isochronous transfer communication period transmission function unit 108, an isochronous transfer communication period acquisition function unit 109, an isochronous transfer timing reception function unit 110, and an isochronous unit 111 at the reception timing. A transfer function unit, an isochronous transfer timing notification function unit of 112, and a group classification function unit of 113, and the functions of the communication device of the fifth embodiment of the present invention and the seventh embodiment of the present invention It also has the functions of communication equipment.
114 communication equipment C includes 116 IEEE 1394 serial bus communication function units and 116 isochronous resource manager function units defined by the IEEE 1394 serial bus standard (see Non-Patent Document 1) and IEEE 1394 serial bus standard (Non-Patent Document 1). 117) and the cycle master function unit defined in (1).
[0021]
102 IEEE 1394 serial bus communication function unit, 107 IEEE 1394 serial bus communication function unit and 115 IEEE 1394 serial bus communication function unit are the same as 202 IEEE 1394 serial bus communication function unit, 103 isochronous transfer communication cycle transmission function unit And 108 isochronous transfer communication cycle transmission function unit is the same as 203 isochronous transfer communication cycle transmission function unit, and 104 isochronous transfer timing reception function unit and 110 isochronous transfer timing reception function unit are 208 isochronous transfer timings. The isochronous transfer function unit at the reception timing 105 and the isochronous transfer function unit at the 111 reception timing are the same functions as the reception function unit, and the isochronous transfer function unit at the 210 reception timing. With the same function, 109 isochronous transfer communication cycle acquisition function unit is the same function as 205 isochronous transfer communication cycle acquisition function unit, 112 isochronous transfer timing notification function unit is the same function as 212 isochronous transfer timing notification function unit, 113 This group classification function unit has the same function as the 214 group classification function unit.
101 communication device A and 106 communication device B are network-connected by 118 IEEE 1394 serial bus A, 106 communication device B and 114 communication device C are network-connected by 119 IEEE 1394 serial bus B, and the 114 communication It is assumed that functions of 116 isochronous resource manager function units and 117 cycle master function units operate in the device C.
The 120 isochronous transfer cycle acquisition process is a process in which the 109 isochronous transfer communication cycle acquisition function unit of the communication device B 106 acquires the isochronous transfer communication cycle from the 103 isochronous transfer cycle transfer function unit of the communication device A 101. The isochronous resource acquisition process is a process in which the communication device B 106 acquires an isochronous resource from the communication device C 114 as an isochronous resource manager, and the isochronous transfer timing notification process 122 is the communication device 106 in FIG. B is a process in which the isochronous transfer cycle timing notification function unit 112 of B notifies the isochronous transfer timing reception function unit 104 of the communication device A 104 of the isochronous transfer timing.
[0022]
FIG. 2 shows an example of isochronous transfer in this embodiment.
126 cycle start packets 1 and 127 cycle start packets 2 and 128 cycle start packets 3 and 129 cycle start packets 4 and 130 cycle start packets 5 are sent by the cycle master. The communication device that becomes the cycle master transfers the packet at 125 specific intervals defined by the IEEE 1394 serial bus standard (see Non-Patent Document 1).
131 isochronous packets A1 and 132 are isochronous packets A2 and 133. The isochronous packet A3 is transferred by a communication device belonging to the group that acquired the isochronous channel A in 123 isochronous transfer communication periods A, and 134 isochronous packets A2 and 133. Packets B1 and 135 of isochronous packet B2 are transferred by a communication device belonging to the group that acquired isochronous channel A in 124 isochronous transfer communication cycle B.
Here, the 123 isochronous transfer communication cycle A is twice the 135 specific interval defined in the IEEE 1394 serial bus standard (see Non-Patent Document 1), and the 124 isochronous transfer communication cycle B is 2 of the 135 specific interval. Is double.
In the above, 123 isochronous transfer communication periods A and 124 isochronous transfer communication periods B are set to twice the specific interval of 135 defined in the IEEE 1394 serial bus standard (see Non-Patent Document 1). It may be an integral multiple of the specific interval of 135, and each isochronous transfer communication cycle may be different.
[0023]
The networks according to the eighth to eleventh embodiments of the present invention will be described with reference to FIGS.
According to the network system of the eighth embodiment, 106 communication devices B are 109 isochronous transfer communication cycle acquisition function units, and the communication of 101 is performed in 120 isochronous transfer cycle acquisition processing via 118 IEEE1394 serial bus A. 123 isochronous transfer communication cycle A is acquired from the isochronous transfer communication cycle transfer function unit 103 of device A.
In addition, the isochronous transfer communication cycle B 124 is acquired from the isochronous transfer cycle transmission function unit 108 of the communication device B 106 which is the own communication device.
According to the network system of this embodiment, 106 communication devices B are 109 isochronous transfer communication cycle acquisition function units and 103 isochronous transfer communication cycle transfer function units are provided with 101 communication devices A and 108 isochronous transfer cycles. By obtaining the isochronous transfer communication cycle from the communication device B 106 provided with the transfer function unit, the communication device B 106 provided with the 109 isochronous transfer communication cycle acquisition function unit is provided with the 103 isochronous transfer communication cycle transfer function unit. The communication cycle of the isochronous transfer between the communication device 101 of 101 and the communication device B of 106 provided with the isochronous transfer communication cycle transmission function unit 108 can be grasped.
[0024]
According to the network system of the ninth embodiment, the communication device B 106 is the group classification function unit 113, and the 123 isochronous transfer communication period A of the 101 communication device A and the self-communication device 106. Recognizing that the isochronous transfer communication cycle 124 of the communication device B is the same, the communication device A 101 and the communication device B 106 are classified into the same group. It is confirmed that the isochronous transfer between the communication device A 101 and the communication device B 106 does not interfere with each other.
In addition, since the communication device A 101 and the communication device B 106 can be classified into the same group, the minimum isochronous resource required for both to perform isochronous transfer is one isochronous channel. It is recognized that the isochronous bandwidth is sufficient to transfer an isochronous packet which is larger of the isochronous packet A1 or the isochronous packet B1 of 134.
Next, the communication device B 106 is a group classification function unit 113, and the 123 isochronous transfer communication cycle A of the communication device A 101 and the 124 isochronous transfer communication cycle B of the communication device B 106 are in accordance with the IEEE 1394 serial bus standard. Since it is twice the specific interval of 135 defined in (Non-Patent Document 1), the cycle start packet transmitted from the cycle master from a specific point in time is counted, and the cycle start packet is The even case is the 136 isochronous transfer timing A of the communication device A 101, and the odd case is the 137 isochronous transfer timing B of the communication device B 106.
[0025]
According to the network system of this embodiment, 106 communication devices B have 113 group classification function units and 103 communication device A and 108 isochronous transfer communication cycle transmission functions having 103 isochronous transfer communication cycle transmission function units. By appropriately dividing 101 communication devices A and 106 communication devices B into groups based on the isochronous transfer communication periods respectively acquired from the 106 communication devices B provided with The communication device B 106 includes an isochronous transfer between the communication device A 101 including the 103 isochronous transfer communication cycle transmission function unit and the communication device B 106 including the isochronous transfer communication cycle transmission function unit 108. Know the minimum required isochronous resources to perform There is an effect that it is a possible to share Sokuronasu resources.
[0026]
According to the network system of the tenth embodiment, 106 communication devices B are 107 IEEE 1394 serial bus communication function units, 101 communication devices A and 108 isochronous equipped with 103 isochronous transfer communication cycle transmission function units. The isochronous resource necessary for performing the isochronous transfer with the communication device B 106 having the transfer communication cycle transmission function unit is obtained by the isochronous resource acquisition process 121 through the 119 IEEE1394 serial bus B. Obtained from 114 communication devices C which are resource managers.
According to the network system of this embodiment, 106 communication devices B are provided with 101 communication devices A provided with 103 isochronous transfer communication cycle transfer function units, and with 106 isochronous transfer communication cycle transfer function units. The 101 communication device having the 103 isochronous transfer communication period transmission function unit by acquiring from the isochronous resource manager all the isochronous resources necessary for performing the isochronous transfer with the communication device B. Preventing two devices A and 108 communication device B having the isochronous transfer communication period transmission function unit from performing isochronous resource acquisition processing and preventing unnecessary acquisition of isochronous resources, respectively. There is an effect that can be done.
[0027]
According to the network system of the eleventh embodiment, 106 communication devices B are 112 isochronous transfer cycle timing notification function units, and 101 communication is performed by 122 isochronous transfer timing notification processing via 118 IEEE1394 serial bus A. The isochronous transfer timing reception function unit 136 is notified to the isochronous transfer timing reception function unit 104 of the device A, and the isochronous transfer timing reception function B of 137 is transmitted to the isochronous transfer timing reception function unit 110 of the communication device B 106 that is the own communication device. Notice.
The communication device A 101 is a cycle start packet that is transmitted by the communication device C 114 at the isochronous transfer function unit 105 at the reception timing 105 at the isochronous transfer timing A 136 received at the isochronous transfer timing reception function unit 104. Isochronous transfer is performed at the same time.
Similarly, the communication device B 106 is an isochronous transfer function unit at a reception timing of 111 at an isochronous transfer timing B of 137 received by an isochronous transfer timing reception function unit of 110, and is isochronous to the cycle start packet. Perform the transfer.
According to the network system of this embodiment, 106 communication devices B having 112 isochronous transfer cycle timing notification function units have 101 isochronous transfer timing reception function units, and 101 communication devices A and 110 have isochronous transfer timings. The communication device B having the reception function unit 106 is notified of the isochronous transfer timing, and the communication device A 101 has received the isochronous transfer timing A at the reception timing of 105 at the 136 isochronous transfer timing A. Then, the communication device B 106 performs the isochronous transfer at the reception timing 111 at the isochronous transfer timing B 137 received by the isochronous transfer function unit 112, thereby causing the isochronous transfer cycle timing 112. The communication device B 106 provided with the notification function unit performs isochronous transfer between the 101 communication device A provided with the 104 isochronous transfer timing reception function unit and the communication device B 106 provided with the 110 isochronous transfer timing reception function unit. There is an effect that the timing can be controlled.
[0028]
【The invention's effect】
  As mentioned above,According to the invention of the IEEE 1394 communication system according to claim 1, transmitting the communication cycle of isochronous transfer of the own communication device to another communication device via the IEEE 1394 serial bus, and acquiring the communication cycle of isochronous transfer from the other communication device; It is possible to obtain the communication cycle of the isochronous transfer of the own communication device without going through the IEEE 1394 serial bus, and transmit the communication cycle of the isochronous transfer of the own communication device to other communication devices via the IEEE 1394 serial bus. And isochronous transfer can be performed at the timing of receiving isochronous transfer from another communication device and the received isochronous transfer timing.
Further, it is possible to acquire the communication cycle of isochronous transfer from another communication device via the IEEE1394 serial bus, notify the timing of isochronous transfer to the other communication device, and classify the communication device into several groups. In addition, transmitting the isochronous transfer communication cycle of the communication device to another communication device via the IEEE1394 serial bus, receiving the isochronous transfer timing, and performing isochronous transfer at the received isochronous transfer timing. It becomes possible to acquire the communication cycle of isochronous transfer from another communication device, notify the timing of isochronous transfer to the other communication device, and classify the communication device into several groups.
  According to the second aspect of the present invention, the isochronous transfer timing is determined in the order in which the isochronous transfer communication cycle acquisition function unit acquires the isochronous transfer communication cycle. However, the order of the node IDs assigned to the communication devices by the IEEE 1394 serial bus is also described. But it gets better, so it ’s more convenient.
[0029]
  According to the third aspect of the present invention, it is possible to prevent the isochronous resource acquisition process from being performed a plurality of times and to prevent wasteful acquisition of isochronous resources.
[0030]
  According to the fourth aspect of the present invention, a communication device including a group classification function unit can control the timing of isochronous transfer of a communication device including an isochronous transfer function unit.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a configuration example of a network system.
FIG. 2 is a diagram illustrating an example of asynchronous transfer.
FIG. 3 is a diagram illustrating a configuration example 1 of a communication device.
FIG. 4 is a diagram illustrating a configuration example 2 of a communication device.
FIG. 5 is a diagram illustrating a configuration example 3 of a communication device.
FIG. 6 is a diagram illustrating a configuration example 4 of a communication device.
FIG. 7 is a diagram illustrating a configuration example 5 of a communication device.
FIG. 8 is a diagram illustrating a configuration example 6 of a communication device.
FIG. 9 is a diagram illustrating a configuration example 7 of a communication device.
FIG. 10 is a diagram illustrating a configuration example 8 of a communication device.
FIG. 11 is a diagram illustrating a configuration example of a conventional network system.
FIG. 12 is a diagram illustrating an example of conventional asynchronous transfer.
[Explanation of symbols]
101 Communication equipment
102 IEEE1394 serial bus communication function unit of communication device A
103 Isochronous transfer communication cycle transmission function unit of communication device A
104 Isochronous transfer timing reception function unit of communication device A
105 Isochronous transfer function at the reception timing of communication device A
106 Communication equipment B
107 IEEE1394 serial bus communication function unit of communication device B
108 Isochronous transfer communication cycle transmission function unit of communication device B
109 Isochronous transfer communication cycle acquisition function part of communication device B
110 Isochronous transfer timing reception function unit of communication device B
111 Isochronous transfer function unit at reception timing of communication device B
112 Isochronous transfer timing notification function part of communication device B
113 Group classification function unit of communication device B
114 Communication equipment C
115 IEEE1394 Serial Bus Communication Function Unit of Communication Equipment C
116 Isochronous Resource Manager Function Unit of Communication Equipment C
117 Cycle Master Function Unit of Communication Equipment C
118 IEEE 1394 Serial Bus A
119 IEEE 1394 serial bus B
120 Isochronous transfer communication cycle acquisition processing
121 Isochronous resource acquisition processing
122 Isochronous transfer timing notification processing
123 Isochronous transfer communication cycle A
124 Isochronous transfer communication cycle B
125 Specific cycle
126 Cycle start packet 1
127 cycle start packet 2
128 cycle start packet 3
129 cycle start packet 4
130 cycle start packet 5
131 Isochronous packet A1
132 Isochronous packet A2
133 Isochronous packet A3
134 Isochronous packet B1
135 Isochronous packet B2
136 Isochronous transfer timing A
137 Isochronous transfer timing B
201, 204, 206, 207, 209, 211, 213, 215 Communication equipment
202 IEEE 1394 serial bus communication function unit
203 Isochronous transfer communication period transmission function part
205 Isochronous transfer communication period acquisition function part
208 Isochronous transfer timing reception function
210 Isochronous transfer function at reception timing
212 Isochronous transfer timing notification function
214 Group classification function
301 Communication equipment A
302 IEEE1394 serial bus communication function unit of communication device A
303 Communication equipment B
304 IEEE1394 serial bus communication function unit of communication device B
305 Isochronous resource manager function part of communication equipment B
306 Cycle master function unit of communication device B
307 Communication equipment C
308 IEEE1394 serial bus communication function unit of communication device C
309 IEEE 1394 serial bus A
310 IEEE1394 Serial Bus B
311 Isochronous Resource Acquisition Processing A
312 Isochronous resource acquisition process B
313 Isochronous transfer communication cycle A
314 Isochronous transfer communication cycle B
315 Specific cycle
316 Cycle start packet 1
317 cycle start packet 2
318 cycle start packet 3
319 Cycle start packet 4
320 cycle start packet 5
321 Isochronous packet A1
322 Isochronous packet A2
323 Isochronous packet A3
324 Isochronous packet B1
325 Isochronous packet B2

Claims (4)

In an IEEE 1394 communication system that includes at least one first communication device and one second communication device and performs communication at a communication cycle that is an integral multiple of the isochronous transfer cycle.
  The first communication device includes an isochronous transfer communication cycle transmission function unit that transmits its own isochronous transfer communication cycle, an isochronous transfer timing reception function unit that receives a timing at which its own communication device performs isochronous transfer, and the received An isochronous transfer function unit that performs isochronous transfer at isochronous transfer timing, and
  The second communication device includes an isochronous transfer communication cycle transmission function unit that transmits its own isochronous transfer communication cycle, and an isochronous transfer communication cycle acquisition function unit that acquires the isochronous transfer communication cycle of itself and the first communication device. Grouping the acquired self and the first communication device having the same isochronous transfer communication period, acquiring communication resources necessary for the group and the first communication device, A group classification function unit for determining isochronous transfer timing of the first communication device, an isochronous transfer timing notification function unit for notifying the self of the group and the first communication device of the isochronous transfer timing, and the isochronous transfer timing. Receive the isochronous transfer IEEE1394 communication system, wherein the timing receiving function unit, and the isochronous transfer function unit for executing the isochronous transfer in the isochronous transfer timing the receipt by comprising. The group classification function unit of the second communication device is
The order in which the isochronous transfer communication cycle acquisition function unit acquires the isochronous transfer communication cycle from itself and the first communication device, and the order in the same group, or the node IDs of the self and the first communication device The IEEE 1394 communication system according to claim 1, wherein the isochronous transfer timing is determined in accordance with the order of the same group. In the IEEE1394 communication system according to claim 1 or 2 ,
Any one communication device having an isochronous resource manager function unit becomes an isochronous resource manager, and the communication device having the group classification function unit is an isochronous device necessary for the communication device performing isochronous transfer to perform isochronous transfer. An IEEE 1394 communication system characterized in that resources are collectively acquired from the isochronous resource manager. The IEEE 1394 communication system according to claim 3 ,
Any one communication device having the cycle master function unit becomes the cycle master, and the communication device having the group classification function unit notifies the timing of isochronous transfer to the communication device performing isochronous transfer, and receives the notification. The IEEE 1394 communication system, wherein the communication device performs isochronous transfer at the notified isochronous transfer timing.

Images