JP6450272B2 - Terminal station apparatus and bandwidth allocation method - Google Patents

Description

  The present invention relates to a terminal station apparatus and a bandwidth allocation method.

  Optical access, represented by FTTH (Fiber To The Home), provides economical services by using a passive optical network (PON) in which a terminal equipment and multiple terminal equipment are connected. Realized. In a passive optical communication network, communication between a terminal device and a terminal device is multiplexed by a time division multiplexing method. On the other hand, communication from a terminal device to a terminal device (hereinafter referred to as “uplink communication”) is realized using a control protocol called MPCP (Multi-Point Control Protocol) (for example, see Non-Patent Document 1). ). The transmission amount and transmission start time in uplink communication of each terminal device are centrally controlled in the terminal device, and the control method dynamically changes the transmission amount and static bandwidth allocation that gives the transmission amount fixedly. It can be roughly divided into dynamic bandwidth allocation. As one of dynamic bandwidth allocation, there is one that achieves high bandwidth utilization efficiency by determining a transmission amount using a request amount from each terminal device (see, for example, Patent Document 1).

  Studies are also being made to apply a passive optical communication network to mobile radio communication service networks (hereinafter referred to as “mobile networks”) represented by LTE (Long Term Evolution) and LTE-advanced to make the network more economical. ing. For example, the function of a conventional radio base station is divided into a base station apparatus unit that performs baseband processing and a radio apparatus unit that performs radio processing. Then, the base station apparatus unit is aggregated in the accommodation station and the radio apparatus unit is extended, and a passive optical communication network is applied to a transmission system between the base station apparatus unit and the radio apparatus unit (for example, Patent Documents). 2). In a mobile network, since retransmission control (HARQ: hybrid automatic repeat request) is performed, requirements for delay time between a base station apparatus unit and a radio apparatus unit are severe. Therefore, the uplink communication transmission start time and the transmission permission amount from the terminal device to the terminal device are calculated based on the uplink communication scheduling information notified from the upper device to the user device via the lower device, and notified. (For example, refer to Patent Document 2). As a result, it is possible to transfer an upstream signal from the lower apparatus to the upper apparatus with a low delay.

Japanese Patent No. 3768421 International Publication No. 2014/077168

"IEEE Std. 802.3-2012", IEEE, 2012

  As described above, when a passive optical communication network is used as a transmission system in which both FTTH and a mobile network relay those communications, the same passive optical communication network uses the same FTTH and the mobile network in order to make the best use of the economy. It is assumed that both service network systems will be accommodated. Since the mobile network supports HARQ, extremely strict low latency is required. On the other hand, in FTTH, in order to achieve high throughput in TCP (Transmission Control Protocol) which is a main protocol in the Internet, low delay is important. Therefore, both of the service network systems need to have a low delay, and a reduction in delay time required for exchanging the MPCP control protocol in the uplink communication of the passive optical communication network has been demanded.

  In view of the above circumstances, the present invention provides a terminal device and a bandwidth allocation method capable of reducing the time required for bandwidth allocation for communication of a plurality of services simultaneously accommodated in a transmission system. It is aimed.

One aspect of the present invention includes a terminal device and a plurality of terminal devices, and performs communication of a plurality of services between a host device connected to the terminal device and a lower device connected to the terminal device. The terminal device in the transmission system for relaying, wherein a bandwidth is allocated to the termination device that relays communication of a part of the plurality of services, and the remaining bandwidth after the allocation is terminated to a bandwidth-unassigned bandwidth A bandwidth allocating unit that distributes and allocates to devices, and determines a transmission start timing of the terminating device based on the allocated bandwidth, and the part of services is a scheduling that indicates a communication schedule from the host device A service to which information is notified or a service to which the scheduling information is not notified, and the bandwidth allocation unit is notified of the scheduling information. The band of the termination device for relaying communication of the service, allocating utilizing amount of bandwidth required for communication obtained on the basis of the scheduling information.

  Further, one aspect of the present invention is the terminal device described above, wherein the bandwidth allocation unit has a transmission start timing of the terminal device that relays the communication of the service notified of the scheduling information, The transmission start timing of the termination device is determined before or after the transmission start timing of the termination device.

  One aspect of the present invention is the terminal device described above, wherein the band allocating unit divides the band allocated to the terminal device, and starts transmission of the terminal device for each of the divided bands. Determine timing.

One aspect of the present invention is the terminal device described above, wherein the bandwidth allocating unit allocates a bandwidth to the terminating device that relays communication of a part of the plurality of services , and further includes a bandwidth The bandwidth of the plurality of services is still allocated to the remaining bandwidth after the fixed amount of bandwidth is allocated to the terminating device that relays communication of some of the services other than the services to which the services are allocated. Distribution is performed to the terminal device that relays communication of services that are not performed based on the bandwidth request amount notified from the terminal device.

One embodiment of the present invention includes a terminal device and a plurality of termination devices, and a plurality of services between a host device connected to the terminal device and a lower device connected to the terminal device. A bandwidth allocation method executed by the terminal device in a transmission system for relaying communication, wherein a bandwidth is allocated to the terminating device that relays communication of a part of services of the plurality of services, and a remaining bandwidth after allocation is determined. , possess a bandwidth allocation allocating to distribute the terminating device bandwidth is not allocated, the timing determination step of determining the timing of the start of transmission of the termination device based on the bandwidth assigned, the said one This service is a service in which scheduling information indicating a communication schedule is notified from the host device or a service in which the scheduling information is not notified. In the bandwidth allocation step, the bandwidth of the terminal device that relays the communication of the service for which the scheduling information has been notified is used as the bandwidth required for the communication obtained based on the scheduling information. Assign .

  According to the present invention, it is possible to reduce the time required for performing bandwidth allocation for communication of a plurality of services simultaneously accommodated in a transmission system.

1 is a configuration diagram of a communication system according to a first embodiment. It is a functional block diagram which shows the structure of the terminal station apparatus by the embodiment. It is a figure which shows the operation | movement flow of the information extraction process which the information extraction part of the terminal device by the same embodiment performs. It is a figure which shows the operation | movement flow of the request amount calculation process which the request amount calculation part of the terminal station apparatus by the same embodiment performs. It is a figure which shows the operation | movement flow of the SLA preservation | save process which the SLA preservation | save part of the terminal station apparatus by the same embodiment performs. It is a figure which shows the operation | movement flow of the band allocation process which the band allocation part of the terminal station apparatus by the same embodiment performs. It is a figure which shows the example of the determination method of the transmission start time by the embodiment. It is a figure which shows the example of the determination method of the transmission start time by the embodiment. It is a figure which shows the example of the determination method of the transmission start time by the embodiment. It is a functional block diagram which shows the structure of the terminal station apparatus by 2nd Embodiment. It is a figure which shows the operation | movement flow of the traffic monitoring process which the traffic monitoring part of the terminal device by the same embodiment performs. It is a functional block diagram which shows the structure of the terminal station apparatus by 3rd Embodiment. It is a figure which shows the operation | movement flow of the band allocation process which the band allocation part of the terminal station apparatus by the same embodiment performs.

Embodiments of the present invention will be described in detail with reference to the drawings. In addition, in this specification and drawing, the component with the same code | symbol shall show the mutually same thing.
In the embodiment of the present invention, a plurality of services are accommodated simultaneously in the transmission system. The case where the transmission system accommodates the service indicates that the communication of the service is relayed. Below, the case where a passive optical network (PON: Passive Optical Network) system is used for a transmission system is demonstrated to an example.

(First embodiment)
A first embodiment of the present invention will be described with reference to FIGS.
FIG. 1 is a configuration diagram of a communication system 10 according to the present embodiment. As shown in the figure, the communication system 10 includes a host device 1a and 1b, a terminal device 2, a terminal device 3a of P units (P is an integer of 1 or more), and Q units (Q is an integer of 1 or more). ) Terminal device 3b, P subordinate devices 4a, and Q subordinate devices 4b.
In the figure, P terminal devices 3a are described as terminal devices 3a-1 to 3a-P, respectively, and Q terminal devices 3b are described as terminal devices 3b-1 to 3b-Q, respectively. In the figure, P subordinate devices 4a are indicated as subordinate devices 4a-1 to 4a-P, respectively, and Q subordinate devices 4b are indicated as subordinate devices 4b-1 to 4b-Q, respectively. Terminating devices 3a-p (p is an integer from 1 to P) are connected to lower devices 4a-p, and terminating devices 3b-q (q is an integer from 1 to Q) are connected to lower devices 4b-q. .
Hereinafter, the upper devices 1a and 1b are collectively referred to as the upper device 1, the termination devices 3a and 3b are collectively referred to as the termination device 3, and the lower devices 4a and 4b are collectively referred to as the lower devices. Described as 4.

  The upper device 1 and the lower device 4 are different for each service to be accommodated. Here, the upper apparatus 1a and the lower apparatus 4a accommodate the A system, and the upper apparatus 1b and the lower apparatus 4b accommodate the B system. The A system is a mobile network that accommodates mobile radio communication services, for example. In the A system, the upper apparatus 1a is a base station apparatus section, and the lower apparatus 4a is a radio apparatus section. The B system is, for example, an FTTH that accommodates a data communication service. In the B system, the upper device 1b is a line collecting switch, and the lower device 4b is a home gateway. The host device 1a and the host device 1b are each connected to a host network. In the case of a mobile network, one or more user devices 5 are further connected to the end of the lower device 4a.

  The terminal device 2 and the terminal device 3 constitute a passive optical communication network. For example, the terminal device 2 is an OLT (Optical Line Terminal), and the termination device 3 is an ONU (Optical Network Unit: optical subscriber line network device). The terminal device 2 and the terminal device 3 are one-to-many connected by a relay network using the optical fiber 6 and the optical splitter 7. That is, the terminal station device 2, the terminal devices 3 a-1 to 3 a -P, and the terminal devices 3 b-1 to 3 b -Q distribute the communication signal transmitted through one optical fiber 6 to a plurality by the optical splitter 7. Connected. The terminal device 2 multiplexes and transmits signals (downlink signals) to be transmitted to the terminal devices 3a-1 to 3a-P and the terminal devices 3b-1 to 3b-Q by the TDM method. The optical splitter 7 transfers the multiplexed downstream signal as it is to the terminal devices 3a-1 to 3a-P and the terminal devices 3b-1 to 3b-Q. Further, signals (uplink signals) transmitted from the terminal devices 3a-1 to 3a-P and the terminal devices 3b-1 to 3b-Q to the terminal device 2 are transmitted by the optical splitter 7 in a TDMA (Time Division Multiple Access) system. Multiplexed and transmitted to the terminal device 2.

  FIG. 2 is a functional block diagram showing a configuration of the terminal device 2 in the present embodiment, and only functional blocks related to the present embodiment are extracted and shown. The terminal device 2 includes an upper transmission / reception unit 201, a lower transmission / reception unit 202, an information extraction unit 203, a request amount calculation unit 204, an SLA (Service Level Agreement) storage unit 205, and a band allocation unit 206.

  The upper transmission / reception unit 201 is an interface responsible for data transmission / reception with the upper apparatus 1. The lower transmission / reception unit 202 is an interface responsible for data transmission / reception with the terminal device 3. The information extraction unit 203 receives scheduling information indicating a communication schedule of the system A from the higher-level device 1a and extracts necessary information. Based on the information extracted by the information extraction unit 203, the request amount calculation unit 204 calculates a relay network request amount that is a bandwidth amount necessary for the uplink communication by the terminating device 3a belonging to the A system. The SLA storage unit 205 stores the SLA of each terminal device 3. The SLA indicates how much communication quality is guaranteed. Here, the SLA is in the range of 1 (low) to N (high). The bandwidth allocating unit 206 calculates the transmission permission for the relay network for uplink communication for each terminal device 3. The relay network transmission permission includes a transmission start time and a transmission permission amount. Information indicating the transmission permission for the relay network calculated by the bandwidth allocating unit 206 is notified to the terminating device 3 via the lower-level transmission / reception unit 202.

  In the present embodiment, the scheduling information is reported from the host device 1a through an interface different from the main signal (the signal from the host device 1a to the user device 5 or the lower device 4a). It may be included in the signal. In this case, the terminal device 2 does not have an interface for receiving scheduling information, and the higher-level transmission / reception unit 201 snoops the scheduling information from the main signal received from the higher-level device 1 a and transfers the scheduling information to the information extraction unit 203.

  FIG. 3 is a diagram illustrating an operation flow of an information extraction process executed by the information extraction unit 203 of the terminal device 2. The information extraction unit 203 executes an information extraction process every time scheduling information is received from the host device 1a. The information extraction unit 203 may collect the received scheduling information and execute the information extraction process at regular intervals.

  In the information extraction step, the information extraction unit 203 extracts destination information indicating the destination user apparatus 5 and allocation information related to transmission of an uplink signal of the user apparatus 5 from the received scheduling information (step S301). The allocation information is information that can acquire the transmission timing and transmission amount of uplink communication allocated to the user apparatus 5. The information extraction unit 203 estimates the time when the uplink communication data (uplink signal) from the user apparatus 5 arrives at the termination apparatus 3a using the time when the scheduling information is received (step S302). Let the estimated time be the estimated arrival time. The information extraction unit 203 transfers the destination information, the allocation information, and the estimated arrival time to the request amount calculation unit 204 (Step S303).

FIG. 4 is a diagram illustrating an operation flow of a request amount calculation process executed by the request amount calculation unit 204 of the terminal device 2. The request amount calculation unit 204 executes a request amount calculation step at intervals of the bandwidth allocation cycle.
In the request amount calculation step, the request amount calculation unit 204 uses the destination information, the allocation information, and the estimated arrival time received from the information extraction unit 203 to calculate the amount of data that arrives at each terminal device 3a for each bandwidth allocation period. (Step S401). The request amount calculation unit 204 transfers the arrival data amount for each termination device 3a in the next bandwidth allocation cycle to the bandwidth allocation unit 206 as the transmission request amount of the termination device 3a, that is, the relay network request amount (step S402). .

  FIG. 5 is a diagram showing an operation flow of the SLA storage process executed by the SLA storage unit 205 of the terminal device 2. The SLA storage unit 205 executes the SLA storage process every time the SLA of any terminal device 3 is changed. In the SLA storage step, when the SLA of any terminal device 3 is changed, the SLA storage unit 205 stores the changed SLA of the terminal device 3 and transfers it to the bandwidth allocation unit 206 (step S501). .

FIG. 6 is a diagram showing an operation flow of the bandwidth allocation process executed by the bandwidth allocation unit 206 of the terminal station device 2. The bandwidth allocation unit 206 executes a bandwidth allocation process at intervals of the bandwidth allocation period.
In the band allocation step, first, the band allocation unit 206 initializes the remaining band C with an allocatable amount in the band allocation period (step S601).

  The bandwidth allocation unit 206 first determines the transmission permission amount of each terminal device 3a belonging to the A system (step S602). Specifically, the bandwidth allocating unit 206 selects the terminal devices 3a belonging to the A system in an arbitrary order or a predetermined order, and performs the processes in steps S603 to S604 below for each of the selected terminal devices 3a. Run. Whether each terminal device 3 belongs to the A system or the B system is manually set in advance for the terminal device 2. Alternatively, the bandwidth allocating unit 206 may change all the terminal devices 3 to belong to the B system in advance and to belong to the A system based on the received scheduling information. For example, the bandwidth allocating unit 206 selects the termination device 3 connected to the lower device 4a to which the user device 5 set in the scheduling information belongs, or the termination device 3 connected to the lower device 4a that is the transmission destination of the scheduling information. , The terminal device belongs to the A system.

  The bandwidth allocating unit 206 determines a transmission permission amount based on the requested amount of the selected termination device 3a and the current remaining bandwidth C (step S603). In other words, the bandwidth allocation unit 206 sets the transmission permission amount of the selected termination device 3a to be the smaller one of the relay network request amount (transmission request amount) of the termination device 3a and the remaining bandwidth C. The bandwidth allocation unit 206 updates the remaining bandwidth C to a value obtained by subtracting the transmission permission amount of the selected termination device 3a from the current value (step S604). If the bandwidth allocation unit 206 determines that the processing of steps S603 to S604 has been executed for all the terminal devices 3a belonging to the A system, the bandwidth allocation unit 206 performs the processing of step S605.

  The bandwidth allocating unit 206 determines the transmission permission amount of each termination device 3b belonging to the B system (step S605). Specifically, the bandwidth allocating unit 206 selects the terminal devices 3b belonging to the B system in an arbitrary order or in a predetermined order, and performs the processes in steps S606 to S607 below for each of the selected terminal devices 3b. Execute. That is, the bandwidth allocation unit 206 determines a distribution amount for the selected termination device 3b in the remaining bandwidth C (step S606). The bandwidth allocation unit 206 allocates the determined distribution amount as a transmission permission amount to the selected termination device 3b (step S607).

  When the distribution amount for the terminal device 3b-x is B (x) and the SLA of the terminal device 3b-x (x is any integer between 1 and Q) is S (x), the remaining bandwidth C is expressed by the following equation: As shown in (1), the distribution is performed in a form proportional to the SLA of each terminal device 3b.

  Further, a minimum guaranteed amount may be assigned to each terminal device 3. If the minimum guaranteed amount of the termination device 3b-x is G (x), the remaining bandwidth C may be distributed as in the following equation (2), for example.

  If the bandwidth allocation unit 206 determines that the processing of Steps S606 to S607 has been executed for all the terminal devices 3b belonging to the B system, the bandwidth allocation unit 206 performs the processing of Step S608.

  Note that the bandwidth allocation unit 206 may allocate a preset fixed amount as the transmission permission amount of the terminating device 3b belonging to the B system. In this case, there may be a remaining bandwidth after the transmission permission amount is allocated to all the terminal devices 3b belonging to the B system. When the communication system 10 accommodates a C system of a service that does not require low latency, the bandwidth allocation unit 206 transmits the remaining bandwidth to the terminal device 3 belonging to the C system from the transmission request amount notified from the terminal device 3. You may distribute based on. The terminal device 3 belonging to the C system is a terminal device 3 connected to the lower device 4 of the C system, and relays communication of services accommodated by the C system.

  The bandwidth allocating unit 206 determines a time length for permitting transmission to each terminal device 3 based on the distribution amount allocated to each terminal device 3. Further, the bandwidth allocation unit 206 determines the transmission start time to be allocated to each terminal device 3 based on the time length permitted for transmission to each terminal device 3 (step S608). The lower transmission / reception unit 202 notifies each terminal device 3 of the transmission permission for the relay network indicating the transmission start time and the transmission permission amount determined by the band allocating unit 206 by a control signal. The band allocating unit 206 may notify each terminal device 3 of the transmission permission for the relay network through a line different from the optical fiber 6.

  FIG. 7 is a diagram illustrating an example of a transmission start time determination method. In the figure, termination devices # 1 and # 2 are termination devices 3a belonging to the A system, and termination devices # 3 to # 5 are termination devices 3b belonging to the B system. The bandwidth allocation unit 206 preferentially allocates transmission start times to the end devices 3a (terminating devices # 1 and # 2) of the A system within the bandwidth allocation cycle at the beginning of the bandwidth allocation cycle, and terminates the B system. A transmission start time later than the transmission start time assigned to the terminal device 3a of the A system is assigned to 3b (terminal devices # 3 to # 5). The band allocating unit 206 collectively allocates the transmission start times of the terminal devices 3a of the A system within the band allocation period to the head of the band allocation period. In this case, the bandwidth allocation unit 206 allocates a transmission start time before the transmission start time allocated to the termination device 3a of the A system to the termination device 3b of the B system in the bandwidth allocation cycle.

The method for determining the transmission start time is not limited to this, and may be determined as shown in FIG. 8 or FIG.
FIG. 8 is a diagram illustrating another example of a transmission start time determination method. The bandwidth allocation unit 206 divides the transmission permission amount of the A system into N. N is an integer equal to or greater than 2, but the figure shows a case where N = 2. The bandwidth allocating unit 206 gives priority to the terminating device 3a (terminating devices # 1, # 2) of the A system, and divides it into a plurality of times (N times) within the bandwidth allocation period for each divided transmission permission amount. A transmission start time is assigned. The bandwidth allocation unit 206 allocates a transmission time to the termination device 3a of the A system, and then allocates a transmission start time to the termination device 3b (termination devices # 3 to # 5) of the B system.

  In this way, when the transmission permission amount of the A system is divided into N and the transmission start time is determined in a plurality of times, the transmission start time is assigned to the remaining time zone for the terminating device 3b of the B system. For this reason, the transmission start time may be determined by dividing the transmission permission amount of a part of the terminal devices 3b of the B system into a plurality of times so as not to overlap with the transmission time of the A system. In the figure, the transmission permission amount of the terminal device # 4 is divided.

  FIG. 9 is a diagram illustrating still another example of the method for determining the transmission start time. In the figure, the bandwidth allocation unit 206 divides the transmission permission amount of the A system and the transmission permission amount of the B system into N (N is an integer of 2 or more). In the figure, the case of N = 2 is shown. The bandwidth allocating unit 206 gives priority to the terminating device 3a (terminating devices # 1, # 2) of the A system, and divides it into a plurality of times (N times) within the bandwidth allocation period for each divided transmission permission amount. Allocate a transmission start time. Further, the bandwidth allocation unit 206 divides the transmission permission amount divided into the remaining bandwidth within the bandwidth allocation cycle a plurality of times (N times) with respect to the terminal device 3b (terminal devices # 3 to # 5) of the B system. Each time a transmission start time is assigned.

  By performing the above processing, the terminal station device 2 uses the scheduling information for the uplink transmission from each terminal device 3a of the A system, thereby grasping the uplink data amount before the uplink data arrives. Assignment can be made. In addition, for the B system, the terminal station device 2 distributes the remaining bandwidth, which is a vacant bandwidth of the bandwidth allocation cycle after performing bandwidth allocation to the A system, without waiting for the transmission request amount from each terminal device 3b. By doing so, bandwidth allocation can be performed. Accordingly, it is possible to reduce the delay of uplink transmission in both the A system and the B system.

If the transmission interval of one terminal device 3 is large, the time until another terminal device 3 waits for the next transmission timing is extended, and the delay increases. Therefore, the bandwidth allocation unit 206 can divide the transmission opportunity of one terminal device 3 into a plurality of times, thereby narrowing the transmission interval of the terminal device 3 as a whole and reducing delay. Therefore, it is possible to assign a high frequency band to each terminal device 3.
Note that this embodiment is applicable even if the termination device 3 is P2PWDM and functions differently from other termination devices 3 and is similar to some services.

  When the entire band of the band allocation period is used up by the system A, the system B may not allocate a band in the band allocation period. Alternatively, a certain amount of bandwidth allocation period may be secured in advance so that it can be allocated to the system B. In this case, the allocation permission amount set for the remaining bandwidth C in step S601 is a value excluding the bandwidth amount reserved for the system B. The bandwidth allocation unit 206 adds the amount of bandwidth reserved for the system B to the remaining bandwidth C before the process of step S605.

(Second Embodiment)
The second embodiment will be described with reference to FIGS. In the present embodiment, the terminal station device uses the past uplink data reception amount (hereinafter referred to as uplink reception amount) of each termination device 3b belonging to the B system and the past bandwidth allocation result to the termination device 3b belonging to the B system. Perform bandwidth allocation for the next period. Hereinafter, the difference from the first embodiment will be mainly described.

The configuration of the communication system of the present embodiment is a configuration in which the terminal station device 2 of the communication system 10 of the first embodiment shown in FIG. 1 is replaced with a terminal station device 12 shown in FIG.
FIG. 10 is a functional block diagram showing a configuration of the terminal device 12 according to the present embodiment, and only functional blocks related to the present embodiment are extracted and shown. In this figure, the same parts as those of the terminal device 2 according to the first embodiment shown in FIG. The terminal device 12 is different from the terminal device 2 of the first embodiment in that it includes a traffic monitor unit 1001 and a band allocation unit 1002 instead of the SLA storage unit 205 and the band allocation unit 206. The traffic monitor unit 1001 measures the uplink reception amount of each terminating device 3b. The bandwidth allocation unit 1002 performs bandwidth allocation using the scheduling information notified from the host device 1a and the uplink reception amount measured by the traffic monitor unit 1001.

  FIG. 11 is a diagram illustrating an operation flow of a traffic monitoring process executed by the traffic monitoring unit 1001 of the terminal station device 12. The traffic monitor unit 1001 sets the initial value of the uplink reception amount to 0, and integrates the uplink reception amount of the termination device 3b each time the lower transmission / reception unit 202 receives the uplink data from the termination device 3b. The traffic monitoring unit 1001 executes a traffic monitoring process at an arbitrary timing. The arbitrary timing is, for example, an interval of the band allocation period.

  In the traffic monitoring step, the traffic monitoring unit 1001 transfers the result of integrating the received uplink amounts for each termination device 3b to the bandwidth allocation unit 1002 (step S1101). After the transfer, the traffic monitor unit 1001 resets the uplink reception amount of each terminating device 3b to 0 (step S1102).

The operation flow of the bandwidth allocation process executed by the bandwidth allocation unit 1002 is the same as the operation flow of the first embodiment shown in FIG. 6, but in step S606, the distribution amount for the terminal device 3b is determined from the remaining bandwidth C. Processing contents are different. In the present embodiment, the ratio between the past uplink reception amount and the transmission permission amount is used to determine the distribution amount for each terminal device 3b. Specifically, assuming that the initial value of the distribution amount for the terminal device 3b-x is B ₀ (x) and the initial value of the remaining bandwidth C is C ₀ , the bandwidth allocation unit 1002 sets B ₀ (x) and C ₀ as Initialization is performed according to the following equations (3) and (4), respectively. G (x) is the minimum guaranteed amount of the terminating device 3b-x.

  Assuming that the past transmission permission amount of the terminating device 3b-x is A (x), the bandwidth allocating unit 1002 performs the terminating device 3b in descending order of A (x) as shown in the following equations (5) and (6). The distribution amount B (x) of −x is sequentially determined, and the remaining bandwidth C is updated.

  In the above equation (5), α is an expansion coefficient with respect to the allocated amount, and is set, for example, as in the following equation (7) according to the ratio of the uplink received amount R (x) and the permitted transmission amount A (x). To do.

  By setting the expansion coefficient α as described above, the transmission permission amount is increased for the terminal device 3b having a high usage rate of the transmission permission amount A (x), and for the terminal device 3b having a low usage rate. Reduce the transmission permission amount. The range of the usage rate and the value of the expansion factor α can be arbitrarily set under the condition that the higher the usage rate, the larger the value of the expansion factor α.

  When the entire bandwidth of the bandwidth allocation cycle is used up by the system A, the system B may not allocate the bandwidth in the bandwidth allocation cycle, and the transmission permission amount that could not be allocated to the terminal device 3 of the system B May be added to the transmission permission amount of the next band allocation cycle. Alternatively, a certain amount of bandwidth allocation period may be secured in advance so that it can be allocated to the system B.

  By performing the above processing, the terminal station device 12 uses the scheduling information for the upstream transmission from each terminal device 3a of the A system, thereby increasing the amount of upstream data of the terminal device 3a before the upstream data arrives. It is possible to grasp and perform bandwidth allocation. Further, the terminal device 12 can perform bandwidth allocation to the terminal device 3b of the B system without waiting for the transmission request amount from each terminal device 3b. Therefore, it is possible to reduce the upstream transmission delay of both the A system and the B system.

  Furthermore, since the terminal station device 12 determines the transmission permission amount of the terminal device 3b according to the usage rate with respect to the past allocation amount for the B system, it is possible to perform high-accuracy bandwidth allocation. As described above, the terminal device 12 determines the transmission permission amount when performing band allocation. If the difference between this transmission permission amount and the data amount that the terminal device 3b actually wants to transmit is large, There is a decrease in efficiency due to excess, and an increase in delay due to insufficient allocation. Therefore, the terminal device 12 can improve the accuracy of assignment compared with the case of fixed assignment by dynamically assigning the transmission permission amount according to the past bandwidth usage rate.

(Third embodiment)
The third embodiment will be described with reference to FIGS. In this embodiment, the terminal station apparatus allocates a band to the terminal apparatus 3b belonging to the B system, and then performs band allocation in the order of allocation to the terminal apparatus 3a belonging to the A system. The difference from the first embodiment lies in the band allocation step executed in the band allocation unit, and the other points are the same as in the first embodiment. Below, it demonstrates centering on the difference with 1st Embodiment.

The configuration of the communication system of this embodiment is a configuration in which the terminal station device 2 of the communication system 10 of the first embodiment shown in FIG. 1 is replaced with a terminal station device 22 shown in FIG.
FIG. 12 is a functional block diagram showing the configuration of the terminal device 22 according to the present embodiment, and only functional blocks related to the present embodiment are extracted and shown. In this figure, the same parts as those of the terminal device 2 according to the first embodiment shown in FIG. The terminal device 22 is different from the terminal device 2 of the first embodiment in that it includes a traffic monitor unit 1001 and a band allocation unit 2002 in place of the SLA storage unit 205 and the band allocation unit 206. The traffic monitor unit 1001 is the same as that of the second embodiment. The bandwidth allocation unit 2002 uses the scheduling information notified from the host device 1a and the uplink received amount measured by the traffic monitor unit 1001 to perform bandwidth allocation with priority on the termination device 3b belonging to the B system. Bandwidth allocation is performed for the terminal device 3a belonging to the A system.

FIG. 13 is a diagram showing an operation flow of a bandwidth allocation process executed by the bandwidth allocation unit 2002 of the terminal station device 22 in this embodiment. The band allocation unit 2002 executes the band allocation process at intervals of the band allocation period.
In the band allocation step, the band allocation unit 2002 initializes the remaining band C with an allocatable amount in the band allocation period (step S601).

  The bandwidth allocation unit 2002 first determines the transmission permission amount of each terminal device 3b belonging to the B system (step S605). Specifically, the bandwidth allocating unit 2002 selects the termination devices 3b belonging to the B system in an arbitrary order or in a predetermined order, and for each of the selected termination devices 3b, the following steps S1201 and S607 are performed. Execute the process.

  The bandwidth allocating unit 2002 allocates a preset parameter for the selected termination device 3b as a transmission permission amount (step S1201). The transmission permission amount may be determined using the past transmission permission amount A (x) and the reception amount R (x) as in the second embodiment. The bandwidth allocating unit 2002 updates the remaining bandwidth C to a value obtained by subtracting the transmission permission amount to the selected terminal device 3b from the current value (step S607).

  If the bandwidth allocation unit 2002 determines that the processing of steps S1201 and S607 has been executed for all the terminal devices 3b belonging to the B system, the bandwidth allocation unit 2002 performs the processing of step S602.

  The bandwidth allocation unit 2002 determines the transmission permission amount of each terminal device 3a belonging to the A system (step S602). Specifically, the bandwidth allocating unit 206 selects the terminal devices 3a belonging to the A system in an arbitrary order or a predetermined order, and for each of the selected terminal devices 3a, steps S603 to S604 shown in FIG. A similar process is executed. That is, the bandwidth allocation unit 2002 determines a transmission permission amount based on the requested amount of the selected termination device 3a and the remaining bandwidth C (step S603). The bandwidth allocation unit 2002 updates the remaining bandwidth C to a value obtained by subtracting the transmission permission amount to the selected termination device 3a from the current value (step S604). If the bandwidth allocation unit 2002 determines that the processing of steps S603 to S604 has been executed for all the terminal devices 3a belonging to the A system, the bandwidth allocation unit 2002 performs the processing of step S608.

  Note that there may be a remaining bandwidth after the transmission permission amount is allocated to all the terminal devices 3a belonging to the A system. When the communication system 10 accommodates a C system of a service that does not require low latency, the bandwidth allocating unit 2002 sends the remaining request bandwidth to the terminating device 3 belonging to the C system from the requested amount of transmission. You may distribute based on.

  The bandwidth allocating unit 2002 determines the length of time during which each terminal device 3 is allowed to transmit based on the distribution amount allocated to each terminal device 3. Further, the band allocation unit 2002 determines the transmission start time of each terminal device 3 based on the time length for which each terminal device 3 is permitted to transmit (step S608). The lower-level transmission / reception unit 202 notifies each terminal device 3 of the transmission permission for the relay network indicating the transmission start time and the transmission permission amount determined by the band allocation unit 2002 by a control signal.

  By performing the above processing, the terminal station device 22 can perform bandwidth allocation to the terminal device 3b of the B system without waiting for the transmission request amount from each terminal device 3b. In addition, for the upstream transmission from each terminal device 3a of the A system, the terminal station device 22 grasps the upstream data amount of the terminal device 3a before arrival of the upstream data from the scheduling information and allocates the bandwidth to the B system. Bandwidth allocation can be performed from the remaining remaining bandwidth. Accordingly, it is possible to reduce the delay of uplink transmission in both the A system and the B system.

  According to the embodiment described above, even when a system using scheduling information and a system not using it are mixed in the service network system accommodated in the passive optical communication network, the delay of the upstream communication of both systems is reduced. Can be realized. For this realization, the terminal device of the passive optical communication network calculates the amount of bandwidth necessary for communication based on the scheduling information notified from the host device for the terminal device that accommodates the mobile network. Bandwidth allocation is executed using the bandwidth. On the other hand, the terminal device performs bandwidth allocation for the terminal device accommodating FTTH based on the SLA of each terminal device or the past uplink communication allocation amount and reception amount of each terminal device. The terminal device determines the transmission start timing of each terminal device based on the band allocated to the terminal device.

  You may make it implement | achieve the function of the terminal station apparatuses 2, 12, and 22 in embodiment mentioned above with a computer. In that case, a program for realizing the functions of the terminal devices 2, 12, and 22 is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system and executed. May be realized. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory inside a computer system serving as a server or a client in that case may be included and a program held for a certain period of time. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

  It can be used in a system that performs communication by time division multiple access.

1a Host device 1b Host devices 2, 12, 22 Terminal devices 3, 3a-1 to 3a-P, 3b-1 to 3b-Q Termination devices 4a-1 to 4a-P, 4b-1 to 4b-Q Subordinate devices 5 User equipment 6 Optical fiber 7 Optical splitter 10 Communication system 201 Upper transmission / reception unit 202 Lower transmission / reception unit 203 Information extraction unit 204 Request amount calculation unit 205 SLA storage units 206, 1002, 2002 Band allocation unit 1001 Traffic monitoring unit

Claims (5)

The terminal in a transmission system having a terminal device and a plurality of terminal devices, and relaying communication of a plurality of services between a host device connected to the terminal device and a lower device connected to the terminal device A station device,
A bandwidth is allocated to the terminal device that relays communication of some services among the plurality of services, and the remaining bandwidth after the allocation is distributed and allocated to the terminal devices to which no bandwidth is allocated. A bandwidth allocation unit for determining a transmission start timing of the termination device based on
Equipped with a,
The partial service is a service in which scheduling information indicating a communication schedule is notified from the host device, or a service in which the scheduling information is not notified,
The bandwidth allocation unit allocates the bandwidth of the terminal device that relays communication of the service for which the scheduling information has been notified, using a bandwidth required for communication obtained based on the scheduling information;
A terminal device characterized by that. The bandwidth allocating unit may transmit the termination so that the transmission start timing of the termination device that relays communication of the service notified of the scheduling information is earlier or later than the transmission start timing of the other termination devices. Determine when to start transmitting the device,
The terminal device according to claim 1 . The band allocation unit divides the band allocated to the termination device, and determines the transmission start timing of the termination device for each of the divided bands;
Terminal device according to claim 1 or claim 2, characterized in that. The band allocating unit allocates a band to the terminating device that relays communication of a part of the plurality of services , and further some other services excluding the part of the services to which the band is allocated The remaining bandwidth after assigning a fixed amount of bandwidth to the terminating device that relays the communication of the communication is transferred from the terminating device to the terminating device that relays communication of a service that has not yet been assigned a bandwidth among the plurality of services. Distribute based on the notified bandwidth request amount,
The terminal device according to any one of claims 1 to 3 , wherein: The terminal in a transmission system having a terminal device and a plurality of terminal devices, and relaying communication of a plurality of services between a host device connected to the terminal device and a lower device connected to the terminal device A bandwidth allocation method executed by a station device,
A bandwidth allocating step of allocating a bandwidth to the terminal device that relays communication of a part of the plurality of services, and distributing and allocating the remaining bandwidth after the allocation to the terminal device to which no bandwidth is allocated;
A timing determination step for determining a transmission start timing of the termination device based on the allocated band;
I have a,
The partial service is a service in which scheduling information indicating a communication schedule is notified from the host device, or a service in which the scheduling information is not notified,
In the bandwidth allocation step, the bandwidth of the terminal device that relays the communication of the service notified of the scheduling information is allocated using the bandwidth required for the communication obtained based on the scheduling information.
A bandwidth allocation method characterized by the above.

Images