WO2023002539A1

WO2023002539A1 - Signal transfer control device, signal transfer control method, signal transfer control program, and signal transfer system

Info

Publication number: WO2023002539A1
Application number: PCT/JP2021/027012
Authority: WO
Inventors: 紘子野村; 慶太高橋; 達也島田
Original assignee: 日本電信電話株式会社
Priority date: 2021-07-19
Filing date: 2021-07-19
Publication date: 2023-01-26
Also published as: JPWO2023002539A1

Abstract

A signal transfer control device according to one embodiment includes: a first acquisition unit that acquires first schedule information indicating a schedule for transferring a signal by a signal transfer device that last transfers a signal to an intermediate node in a first network; a second acquisition unit that acquires processing time information indicating the time required for processing performed in order for the intermediate node to transfer, to a second network, the signal transferred from the first network; a determination unit that determines, on the basis of the first schedule information acquired by the first acquisition unit and the processing time information acquired by the second acquisition unit, second schedule information indicating a schedule at which a signal should be transferred by a signal transfer device that first transfers, in the second network, the signal transferred by the intermediate node; and an output unit that outputs the second schedule information determined by the determination unit to the signal transfer device that first transfers, in the second network, the signal transferred by the intermediate node.

Description

SIGNAL TRANSFER CONTROL DEVICE, SIGNAL TRANSFER CONTROL METHOD, SIGNAL TRANSFER CONTROL PROGRAM AND SIGNAL TRANSFER SYSTEM

The present invention relates to a signal transfer control device, a signal transfer control method, a signal transfer control program, and a signal transfer system.

For example, in 5G (fifth generation mobile communication system), etc., a signal transfer system configured to control traffic including MFH (Mobile Fronthaul), MMH (Mobile Midhaul), and MBH (Mobile Backhaul) is known. there is

For example, a communication path between a plurality of DUs (Distributed Units) to which a plurality of RUs (Radio Units) are connected and a plurality of CUs (Central Units) is a SW (switch ) are switched signal transfer systems.

Also, in a signal transfer system that transfers signals sequentially, packets are generally delayed when passing through a switch. Therefore, various techniques are applied to realize a low-delay network.

For example, TAS (Time Aware Shaper) technology is known as one of the technologies for reducing the delay of high-priority signals. In the TAS, complete priority control is performed, and a transmission time slot is reserved in the signal transfer device for the periodically transmitted priority signals subject to priority control (gates are opened and other priority gates are opened). close). In the priority transmission section, other priority signals cannot be transmitted (waited). In complete priority control, the signal transfer device receives the signal subject to priority control, becomes ready to transmit the signal, and then responds when the transmission of the currently transmitted signal is completed. open a time gate to

In addition, Non-Patent Document 1 defines bridges and LANs for networks that require low latency.

JP 2020-92317 A

However, conventionally, when signals are transferred from a network that transfers signals by TAS, for example, to a network that transfers signals by another TAS via an intermediate node, schedule information could not be linked. Also, in such networks, delay times at intermediate nodes have not been considered.

For example, time slot reservations needed to include a certain fixed amount of time when setting the processing time at intermediate nodes. This fixed time is an estimate. Therefore, in order to have the traffic arrive within the time slot, it is necessary to add a margin to the reserved time, which sometimes reduces the bandwidth utilization efficiency.

The present invention has been made in view of the above-described problems, and provides a signal transfer control device capable of improving band utilization efficiency even when signals are transferred across a plurality of different networks that transfer signals. An object of the present invention is to provide a transfer control method, a signal transfer control program, and a signal transfer system.

A signal transfer control device according to an embodiment of the present invention transfers a signal from a first network, to which a plurality of signal transfer devices transfer signals, to a second network, to which a plurality of signal transfer devices transfer signals, via an intermediate node. in a signal transfer control device for controlling a signal transfer schedule of a signal transfer system that transfers a signal, first schedule information indicating a signal transfer schedule by a signal transfer device that transfers a signal to the intermediate node last in the first network and a second acquisition unit for acquiring processing time information indicating the time required for processing performed by the intermediate node to transfer the signal transferred from the first network to the second network. , based on the first schedule information acquired by the first acquisition unit and the processing time information acquired by the second acquisition unit, signal transfer for first transferring the signal transferred by the intermediate node within the second network a determination unit for determining second schedule information indicating a schedule for a device to transfer a signal; and an output unit for outputting the second schedule information.

Further, in the signal transfer control method according to one embodiment of the present invention, a signal is transferred from a first network, to which a plurality of signal transfer devices transfer signals, to a second network, to which a plurality of signal transfer devices transfer signals, via an intermediate node. a signal transfer control method for controlling a signal transfer schedule of a signal transfer system for transferring signals by means of a signal transfer control method, wherein a signal transfer device for finally transferring a signal to the intermediate node in the first network indicates a signal transfer schedule; a first obtaining step of obtaining schedule information; and a second obtaining step of obtaining processing time information indicating the time required for processing performed by the intermediate node to transfer the signal transferred from the first network to the second network. and a second schedule indicating a schedule by which a signal transfer device that first transfers the signal transferred by the intermediate node within the second network should transfer the signal, based on the first schedule information and the processing time information. and an outputting step of outputting the determined second schedule information to a signal transfer device that first transfers the signal transferred by the intermediate node within the second network. do.

Further, a signal transfer system according to an embodiment of the present invention includes a first network in which a plurality of signal transfer devices transfer signals, a second network in which a plurality of signal transfer devices transfer signals, and a signal from the first network. A signal transfer system comprising: an intermediate node that transfers signals to the second network; and a signal transfer control device that controls a signal transfer schedule for transferring signals from the intermediate node to the second network, wherein the signal transfer control device comprises: a first acquisition unit for acquiring first schedule information indicating a schedule for signal transfer by a signal transfer device that transfers a signal to the intermediate node last in the first network; and a signal transferred from the first network. to the second network by the intermediate node; Determining second schedule information indicating a schedule in which a signal transfer device that first transfers the signal transferred by the intermediate node within the second network should transfer the signal, based on the processing time information obtained by the obtaining unit. and an output unit for outputting the second schedule information determined by the determination unit to a signal transfer device that first transfers the signal transferred by the intermediate node within the second network. .

According to the present invention, band utilization efficiency can be improved even when signals are transferred across a plurality of different networks that transfer signals.

It is a figure which shows the structural example of the signal transfer system concerning one Embodiment. It is a figure which shows the structural example of the signal transfer control apparatus concerning one Embodiment. It is a figure which illustrates the 2nd schedule information which the determination part determined. FIG. 4 is a diagram schematically illustrating a process of determining second schedule information by a signal transfer control device; It is a figure which shows the hardware structural example of the signal transfer control apparatus concerning one Embodiment. FIG. 3 is a diagram showing a configuration example of a signal transfer system of a comparative example; It is a figure which shows the structural example of a signal transfer apparatus. It is a figure which shows the structural example of a signal transfer control apparatus.

First, the background that led to the invention will be explained. FIG. 6 is a diagram showing a configuration example of a signal transfer system 1 of a comparative example. In the signal transfer system 1 , for example, a first network 2 and a second network 3 are connected via a central office 4 . Then, the signal transfer system 1 sends signals so that the distributed stations (lower devices) 10-1 and 10-2 perform two-way communication with the upper device 12 via the first network 2, the central station 4 and the second network 3. forward (traffic). Distributed stations 10-1 and 10-2 (or host device 12) are devices that generate traffic.

The first network 2 has, for example, signal transfer devices 5-1 to 5-4 and a signal transfer control device 6-1. The signal transfer devices 5-1 to 5-4 constitute a plurality of routes for transferring signals between the distributed stations 10-1, 10-2 and the central station 4. FIG.

Then, the signal transfer devices 5-1 to 5-4 transfer the signals transmitted by the decentralized stations 10-1 and 10-2 to the central station 4 by TAS under the control of the signal transfer control device 6-1. Further, the signal transfer devices 5-1 to 5-4 transfer signals transmitted from the central station 4 to the distributed stations 10-1 and 10-2 by TAS under the control of the signal transfer control device 6-1.

The signal transfer control device 6-1 determines a signal transfer route between the distributed stations 10-1, 10-2 and the central office 4, and issues an instruction to transfer the signal through the determined route. and controls the signal transfer devices 5-1 to 5-4.

The second network 3 has, for example, signal transfer devices 5-5 to 5-8 and a signal transfer control device 6-2. The signal transfer devices 5-5 to 5-8 constitute a plurality of routes for transferring signals between the central office 4 and the host device 12. FIG.

Then, the signal transfer devices 5-5 to 5-8 transfer the signal transmitted by the central office 4 to the host device 12 by TAS under the control of the signal transfer control device 6-2. In addition, the signal transfer devices 5-5 to 5-8 transfer signals transmitted from the host device 12 to the central office 4 by TAS under the control of the signal transfer control device 6-2.

A signal transfer control device 6-2 determines a route for transferring a signal between the central office 4 and the host device 12, outputs a command so that the signal is transferred through the decided route, and controls the signal transfer device. 5-5 to 5-8 are controlled.

The central station 4 is, for example, a CU (Central unit: aggregation base station) and serves as an intermediate node that transfers signals from the first network 2 to the second network 3 or from the second network 3 to the first network 2. there is That is, the central office 4 aggregates upstream signals transferred via the first network 2 and transfers them to the second network 3 , and distributes downstream signals transferred via the second network 3 to the first network 2 . and transfer.

Hereinafter, when any one of a plurality of configurations such as signal transfer devices 5-1 to 5-8 is not specified, it is simply referred to as signal transfer device 5 or the like.

FIG. 7 is a diagram showing a configuration example of the signal transfer device 5. As shown in FIG. As shown in FIG. 7, the signal transfer device 5 includes, for example, a receiving section 50, a signal distribution section 51, a buffer section 52, a time gate section 53, a control section 54, and a transmission section 55. Transfer by

The receiving unit 50 receives, for example, a plurality of signals including periodic signals having a higher priority than other signals, and outputs the received signals to the signal distribution unit 51 respectively. The receiving unit 50 also receives the command output by the signal transfer control device 6 and outputs the command to the control unit 54 .

The signal distribution unit 51 has a function of distributing each signal input from the reception unit 50 according to priority, and outputs the signals distributed according to priority to the buffer unit 52 .

The buffer unit 52 includes a plurality of buffers 520 that hold signals for each priority. A plurality of buffers 520 respectively hold signals sorted by the signal sorting unit 51 for each priority. That is, the plurality of buffers 520 hold the plurality of signals received by the receiver 50 according to their priorities.

The time gate section 53 has a plurality of gates 530 corresponding to the plurality of buffers 520 respectively. The gate 530 transmits the signal held by the buffer 520 to the transmitting section 55 by opening, and stops the transmission of the signal held by the buffer 520 to the transmitting section 55 by closing.

The control unit 54 controls signal transmission for each buffer 520 by controlling the opening and closing of each of the plurality of gates 530 included in the time gate unit 53, for example, according to a command (schedule information) notified from the signal transfer control device 6. A scheduler. The schedule information includes the gate opening period and the gate opening start time according to the priority of the signal by TAS.

For example, the control unit 54 executes TAS according to the schedule information notified from the signal transfer control device 6. At this time, the control unit 54 performs control so that the gate 530 is opened at a timing determined based on the cycle information, phase information, and data length of the signal included in the schedule information. For example, the control unit 54 gives priority to the buffer 520 holding a signal with a high priority, and controls to open the corresponding gate 530 .

The transmission unit 55 has a transfer function of transmitting a signal indicating that the gate 530 has been opened to a specified output destination. In other words, the transmitter 55 transmits the signals output by the plurality of buffers 520 under the control of the controller 54 .

FIG. 8 is a diagram showing a configuration example of the signal transfer control device 6. As shown in FIG. As shown in FIG. 8, the signal transfer control device 6 has, for example, a route information storage section 60, a distance information storage section 61, an instruction determination section 62, and an output section 63. FIG.

The route information storage unit 60 stores, for example, route information indicating a plurality of routes configured by a plurality of signal transfer devices 5. Upon access from the command determination unit 62, the route information is sent to the command determination unit 62. Output.

The distance information storage unit 61 stores, for example, distance information indicating the distance of each route indicated by the route information stored in the route information storage unit 60, and is accessed by the command determination unit 62 to determine the distance information. Output to the unit 62 .

The command determination unit 62 determines commands (schedule information) for each of the plurality of signal transfer devices 5 based on the route information and the distance information, and outputs the determined commands to the output unit 63 .

The output unit 63 outputs (transmits) the command output by the command determination unit 62 to each of the plurality of signal transfer devices 5 .

Next, an operation example of the signal transfer system 1 (FIG. 6) will be described. When transferring signals from distributed stations 10-1 and 10-2 to host device 12, first network 2 determines a route via a plurality of signal transfer devices 5 according to the control of signal transfer control device 6-1. Then, the signals transmitted by the decentralized stations 10-1 and 10-2 are transferred to the central station 4 by the TAS through the determined route.

The central office 4 processes the signals transferred by the first network 2 and transfers them to the second network 3 . The second network 3 determines a route via a plurality of signal transfer devices 5 according to the control of the signal transfer control device 6-2, and transfers the signal transferred by the central office 4 through the determined route to the host device 12 by TAS. Forward.

Thus, in signal transfer across the central office 4 in the signal transfer system 1, the schedule information of the first network 2 and the schedule information of the second network 3 are not linked.

In other words, the time slot reservation in the second network 3 must include a certain fixed time when setting the processing time by the central office 4 . This fixed time is an estimate. Therefore, in order to have the traffic arrive within the time slot, it is necessary to add a margin to the reserved time, which sometimes reduces the bandwidth utilization efficiency.

Therefore, the signal transfer system according to one embodiment described below is configured to improve the band utilization efficiency even when signals are transferred across a plurality of different networks that transfer signals by TAS. ing.

FIG. 1 is a diagram showing a configuration example of a signal transfer system 1a according to one embodiment. In the signal transfer system 1a, for example, a first network 2a and a second network 3a are connected via a central office 4a. Then, the signal transfer system 1a sends a signal so that the distributed stations (lower devices) 10-1 and 10-2 perform two-way communication with the upper device 12 via the first network 2a, the central station 4a and the second network 3a. forward (traffic).

In the following, in the signal transfer system 1a shown in FIG. 1, the same reference numerals are assigned to substantially the same configurations as those of the signal transfer system 1 shown in FIG.

The first network 2a has, for example, signal transfer devices 5-1 to 5-4 and a signal transfer control device 7-1. The signal transfer devices 5-1 to 5-4 constitute a plurality of routes for transferring signals between the distributed stations 10-1, 10-2 and the central station 4a.

Then, the signal transfer devices 5-1 to 5-4 transfer the signals transmitted by the decentralized stations 10-1 and 10-2 to the central station 4a by TAS under the control of the signal transfer control device 7-1. Further, the signal transfer devices 5-1 to 5-4 transfer signals transmitted from the central station 4a to the distributed stations 10-1 and 10-2 by TAS under the control of the signal transfer control device 7-1.

The signal transfer control device 7-1 determines a signal transfer route between the distributed stations 10-1, 10-2 and the central office 4a, and issues an instruction to transfer the signal through the decided route. and controls the signal transfer devices 5-1 to 5-4. Also, the signal transfer control device 7-1 transmits schedule information in the first network 2a to the signal transfer control device 7-2. The signal transfer control device 7-1 also has a function of acquiring processing time information (described later) from the central office 4a.

The second network 3a has, for example, signal transfer devices 5-5 to 5-8 and a signal transfer control device 7-2. The signal transfer devices 5-5 to 5-8 constitute a plurality of routes for transferring signals between the central office 4a and the host device 12. FIG.

Then, the signal transfer devices 5-5 to 5-8 transfer the signal transmitted from the central office 4a to the host device 12 by TAS under the control of the signal transfer control device 7-2. Further, the signal transfer devices 5-5 to 5-8 transfer the signal transmitted from the host device 12 to the central office 4a by TAS under the control of the signal transfer control device 7-2.

The signal transfer control device 7-2 determines a route for transferring a signal between the central office 4a and the host device 12, outputs a command so that the signal is transferred through the decided route, and controls the signal transfer device. 5-5 to 5-8 are controlled. Further, the signal transfer control device 7-2 transmits schedule information in the second network 3a to the signal transfer control device 7-1. The signal transfer control device 7-2 also has a function of acquiring processing time information (described later) from the central office 4a.

The central station 4a is, for example, a CU (Central unit: aggregation base station) and serves as an intermediate node that transfers signals from the first network 2a to the second network 3a or from the second network 3a to the first network 2a. there is That is, the central office 4a aggregates upstream signals transferred via the first network 2a and transfers them to the second network 3a, and distributes downstream signals transferred via the second network 3a to the first network 2a. and transfer.

Thus, the signal transfer system 1a transfers signals so that the distributed stations 10-1, 10-2 and the host device 12 can perform two-way communication. A case of transferring a signal will be described as an example.

FIG. 2 is a diagram showing a configuration example of the signal transfer control device 7-2 according to one embodiment. As shown in FIG. 2, the signal transfer control device 7-2 includes, for example, a route information storage unit 70, a distance information storage unit 71, a first acquisition unit 72, an open period calculation unit 73, an acquisition time calculation unit 74, a second acquisition It has a unit 75 , a processing time storage unit 76 , a time acquisition unit 77 , a determination unit 78 and an output unit 79 . For example, the signal transfer controller 7-2 controls the signal transfer schedule for transferring signals from the central office 4a to the second network 3a. The signal transfer control device 7-1 also has the same configuration as the signal transfer control device 7-2.

The route information storage unit 70 stores, for example, route information indicating a plurality of routes configured by a plurality of signal transfer devices 5, and outputs the route information to the determination unit 78 upon access from the determination unit 78. .

The distance information storage unit 71 stores distance information indicating the distance of each route indicated by the route information stored in the route information storage unit 70, for example. Output for

The first acquisition unit 72 acquires first schedule information indicating a schedule for transferring signals by TAS from the signal transfer device 5-2, which transfers the signal to the central office 4a last in the first network 2a, for example, the signal transfer control device 7. -1 is obtained. The first acquisition unit 72 then outputs the acquired first schedule information to the open period calculation unit 73 and the acquisition time calculation unit 74 .

Also, the first acquisition unit 72 may acquire the first schedule information at a predetermined periodic first timing.

The open period calculator 73 acquires function split point information between the central office 4a and the host device 12 within the second network 3a. The open period calculator 73 also acquires absolute time difference information indicating the difference between the time on the first network 2a and the time on the second network 3a. In addition, the open period calculator 73 acquires arrival interval information indicating the time interval between the arrival of processing time information indicating the time required for processing performed by the central office 4a to transfer the signal to the second network 3a. Also, the open period calculator 73 acquires the first schedule information from the first acquirer 72 .

Then, the open period calculation unit 73 calculates the usable band in the second network 3a based on the acquired information, calculates the gate open period of each of the signal transfer devices 5, and calculates, for example, the acquired information. The result is output to the acquisition time calculation section 74 and the output section 79 .

The acquisition time calculation unit 74 calculates an offset value necessary for setting schedule information (gate open period and gate open start time) for the signal transfer device 5-5 that first transfers a signal within the second network 3a. is calculated, and the offset value is output to the time acquisition unit 77 together with arrival interval (acquisition timing) information in absolute time.

The second acquisition unit 75 obtains from the central office 4a processing time information tβ(t) indicating the time required for the processing performed by the central office 4a to transfer the signal transferred from the first network 2a to the second network 3a. get. Then, the second acquisition unit 75 outputs the acquired processing time information and information indicating the interval at which the processing time information arrives from the central office 4a (transmission timing from the central office 4a) to the processing time storage unit 76. .

Also, the second acquisition unit 75 may acquire the processing time information at a predetermined periodic second timing different from the first timing of the first acquisition unit 72 .

The processing time storage unit 76 stores the processing time information tβ(t) input from the second acquisition unit 75 and information indicating the transmission timing from the central office 4a, and outputs in response to access from the time acquisition unit 77. do.

The time acquisition unit 77 receives information (offset value, acquisition timing) input from the acquisition time calculation unit 74 and information acquired from the processing time storage unit 76 (processing time information, information indicating transmission timing from the central station 4a). are associated with each other and output to the determination unit 78 .

Based on the information input from the route information storage unit 70, the distance information storage unit 71, and the time acquisition unit 77, the determination unit 78 first transfers the signal transferred by the central office 4a within the second network 3a. The signal transfer device 5 - 5 determines the second schedule information indicating the schedule to transfer the signal by TAS, and outputs it to the output section 79 .

For example, if the gate open time of the signal transfer device 5-2 is T1, the determination unit 78 sets the gate open time of the signal transfer device 5-5 to be T1+D+tβ(t). D is the transmission time between the signal transfer device 5-2 and the signal transfer device 5-5. Also, the determining unit 78 determines the second schedule information based on the band in which the signal in the second network 3a can be transferred.

FIG. 3 is a diagram exemplifying the second schedule information determined by the determination unit 78. FIG. As shown in FIG. 3, the determination unit 78 determines the gate open period and the gate open opening time as the second schedule information.

That is, based on the first schedule information acquired by the first acquisition unit 72 and the processing time information acquired by the second acquisition unit 75, the determination unit 78 determines the signal transferred by the central office 4a to the signal transfer device 5-5. determines the schedule (second schedule information) to be transferred by TAS. At this time, the determining unit 78 synchronizes the time between the first network 2a and the second network 3a to determine the second schedule information.

Further, the determination unit 78 determines whether the second acquisition unit 75 acquires the time between the time when the first acquisition unit 72 acquires the first schedule information and the time when the second acquisition unit 75 acquires the processing time information. The second schedule information may be determined based on the result of determining whether the processing time information is longer than the time indicated by the processing time information.

FIG. 4 is a diagram schematically illustrating the process of determining the second schedule information by the signal transfer control device 7-2. The signal transfer control device 7-2 outputs second schedule information (gate opening start time, gate opening period) to the signal transfer device 5-5.

In order to synchronize the time between the first network 2a and the second network 3a, the signal transfer control device 7-2 obtains the difference in absolute time, the route information, the distance information, and the processing time of the central office 4a. Set the offset based on

At this time, the timing of acquiring the schedule information of the signal transfer device 5-2 and the transmission of the processing time information by the central office 4a are different. Therefore, the signal transfer control device 7-2 corrects the timing deviation in order to determine the gate opening start time. For example, the signal transfer control device 7-2 performs correction using the most recent processing time of the central office 4a or the average value of the processing time.

Also, the signal transfer control device 7-2 acquires the split point information of MFH and MBH and determines the gate opening period.

For example, the signal transfer control device 7-2 determines the second schedule information using the processing time of the central office 4a that is closest to the schedule timing of the signal transfer device 5-5. For example, it is assumed that the signal transfer control device 7-2 acquires in advance the interval at which the processing time information arrives from the central office 4a (transmission timing from the central office 4a).

Then, when using the notified processing time as an offset, the signal transfer control device 7-2 sets the processing time as follows, for example.

If t_set−t2>processing time: Set the processing time notified at t2.
If t_set−t2≦processing time: Set the processing time notified at t1.

Then, the output unit 79 (FIG. 2) outputs the second schedule information determined by the determination unit 78 to the signal transfer device 5-5 that first transfers the signal transferred by the central office 4a within the second network 3a. do.

For example, the output unit 79 outputs the gate open period and the gate open time enclosed by the dashed lines in FIG. Notify as an order.

Thus, in the signal transfer system 1a, the central office 4a notifies the processing time information tβ(t) to the signal transfer control device 7-2, the signal transfer control device 7-2 determines the second schedule information, The control unit 54 of the signal transfer device 5 is notified of the second schedule information.

Therefore, the signal transfer system 1a according to one embodiment can improve band utilization efficiency even when signals are transferred across a plurality of different networks that transfer signals.

Further, each function of the signal transfer control devices 7-1 and 7-2, the central office 4a, and the signal transfer device 5 is partly or entirely a PLD (Programmable Logic Device) or FPGA (Field Programmable Gate Array). It may be configured by hardware such as a CPU, or may be configured as a program executed by a processor such as a CPU.

For example, the signal transfer control device 7 according to one embodiment can be implemented using a computer and a program, and the program can be recorded on a storage medium or provided through a network.

FIG. 5 is a diagram showing a hardware configuration example of the signal transfer control device 7 according to one embodiment. As shown in FIG. 5, for example, the signal transfer control device 7 has an input section 800, an output section 810, a communication section 820, a CPU 830, a memory 840, and an HDD 850 connected via a bus 860, and functions as a computer. Also, the signal transfer control device 7 can input/output data to/from a computer-readable storage medium 870 .

The input unit 800 is, for example, a keyboard and a mouse. The output unit 810 is, for example, a display device such as a display. The communication unit 820 is, for example, a network interface.

The CPU 830 controls each part that constitutes the signal transfer control device 7 and performs predetermined processing. The memory 840 and HDD 850 are storage units that store data and the like.

The storage medium 870 can store programs and the like for executing the functions of the signal transfer control device 7 . Note that the architecture constituting the signal transfer control device 7 is not limited to the example shown in FIG.

1, 1a... signal transfer system, 2, 2a... first network, 3, 3a... second network, 4, 4a... central office, 5-1 to 5-8... signal Transfer device 6-1, 6-2 Signal transfer control device 7-1, 7-2 Signal transfer control device 10-1, 10-2 Distributed station 12 Host device 50 Reception unit 51 Signal distribution unit 52 Buffer unit 53 Time gate unit 54 Control unit 55 Transmission unit 70. Route information storage unit 71 Distance information storage unit 72 First acquisition unit 73 Open period calculation unit 74 Acquisition time calculation unit 75 Second acquisition Section 76 Processing time storage section 77 Time acquisition section 78 Determination section 79 Output section 520 Buffer 530 Gate 800 Input Unit 810 Output unit 820 Communication unit 830 CPU 840 Memory 850 HDD 860 Bus 870 Storage medium

Claims

A signal that controls the signal transfer schedule of a signal transfer system that transfers signals via intermediate nodes from a first network over which a plurality of signal transfer devices transfer signals to a second network over which a plurality of signal transfer devices transfer signals. In the transfer control device,
a first acquisition unit for acquiring first schedule information indicating a schedule for signal transfer by a signal transfer device that transfers a signal to the intermediate node last in the first network;
a second acquisition unit that acquires processing time information indicating the time required for processing performed by the intermediate node to transfer the signal transferred from the first network to the second network;
A signal transfer device that first transfers a signal transferred by the intermediate node within the second network based on the first schedule information obtained by the first obtaining unit and the processing time information obtained by the second obtaining unit. a determination unit for determining second schedule information indicating a schedule for transferring signals;
and an output unit that outputs the second schedule information determined by the determination unit to a signal transfer device that first transfers the signal transferred by the intermediate node within the second network. Device.
The decision unit
2. The signal transfer control device according to claim 1, wherein the second schedule information is determined by synchronizing the time between the first network and the second network.
The first acquisition unit
acquiring first schedule information at a predetermined periodic first timing;
The second acquisition unit
Acquiring processing time information at a predetermined periodic second timing different from the first timing,
The decision unit
The time between the time when the first acquisition unit acquires the first schedule information and the time when the second acquisition unit acquires the processing time information is the time indicated by the processing time information acquired by the second acquisition unit. 3. The signal transfer control device according to claim 2, wherein the second schedule information is determined based on the result of determining whether or not it is longer than.
The decision unit
The signal transfer control device according to any one of claims 1 to 3, wherein the second schedule information is determined based on a band capable of transferring signals in the second network.
A signal that controls the signal transfer schedule of a signal transfer system that transfers signals via intermediate nodes from a first network over which a plurality of signal transfer devices transfer signals to a second network over which a plurality of signal transfer devices transfer signals. In the transfer control method,
a first obtaining step of obtaining first schedule information indicating a schedule for transferring a signal by a signal transfer device that transfers a signal to the intermediate node last in the first network;
a second obtaining step of obtaining processing time information indicating a time required for processing performed by the intermediate node to transfer the signal transferred from the first network to the second network;
Based on the first schedule information and the processing time information, second schedule information is determined that indicates a schedule in which the signal transfer device that first transfers the signal transferred by the intermediate node within the second network should transfer the signal. a decision process to
and an output step of outputting the determined second schedule information to a signal transfer device that first transfers the signal transferred by the intermediate node within the second network.
A signal transfer control program for causing a computer to function as each part of the signal transfer control device according to any one of claims 1 to 4.
a first network through which a plurality of signal transfer devices transfer signals;
a second network through which a plurality of signal transfer devices transfer signals;
an intermediate node that transfers signals from the first network to the second network;
a signal transfer controller for controlling a signal transfer schedule for transferring signals from the intermediate node to the second network,
The signal transfer control device is
a first acquisition unit for acquiring first schedule information indicating a schedule for signal transfer by a signal transfer device that transfers a signal to the intermediate node last in the first network;
a second acquisition unit that acquires processing time information indicating the time required for processing performed by the intermediate node to transfer the signal transferred from the first network to the second network;
A signal transfer device that first transfers a signal transferred by the intermediate node within the second network based on the first schedule information obtained by the first obtaining unit and the processing time information obtained by the second obtaining unit. a determination unit for determining second schedule information indicating a schedule for transferring signals;
and an output unit for outputting the second schedule information determined by the determining unit to a signal transfer device that first transfers the signal transferred by the intermediate node within the second network. .
The decision unit
8. The signal transfer system according to claim 7, wherein the second schedule information is determined by synchronizing time between the first network and the second network.