JP2003298604A - Communication system and management method for communication band - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To effectively and dynamically allocate upward bands from subscriber devices to a station apparatus in a point-to-multipoint configuration in which the station apparatus covers a plurality of subscriber devices. <P>SOLUTION: When a convergence occurs or is recovered in the subscriber devices, the subscriber devices notify buffer storage amounts to the station apparatus and shorten a response time from the occurrence or recovery of the convergence up to the reallocation of bands by shortening in the station apparatus monitoring the intervals of notifications of the buffer storage amounts from the subscriber devices. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a point-to-multipoint configuration in which a station side device accommodates a plurality of subscriber devices and dynamically changes the communication band of upstream communication from the subscriber side to the master station side. The present invention relates to a communication system to be assigned.

[0002]

2. Description of the Related Art As a conventional technique, for example, Japanese Unexamined Patent Publication No. Hei 11
-252035 “Bandwidth allocation method and transmission system”. FIG. 1 is a diagram showing a conventional configuration, which will be described. Reference numeral 1 is a station side device. 2 is the station side device 1
It is a congestion detector provided in the. Reference numeral 3 is a band allocation unit provided in the station side device 1. Reference numeral 4 is a multi-branching device. 5
a, 5b, 5c are subscriber devices. 6a, 6b, 6c
Are buffers for the subscriber devices 5a to 5c to store data, respectively, and are provided in the subscriber devices 5a to 5c.

FIGS. 6, 7, and 8 are diagrams showing a conventional operation, which will be described. Note that FIG. 6, FIG. 7, and FIG.
The meanings of the symbols shown in are as shown in FIG. First, FIG. 6 showing the operation of the upstream communication system will be described. t
Is a time axis, and times t1, t2, and t3 represent 1 frame, 2 frames, and 3 frames, respectively. The station equipment is
The upstream transmission path is set to TDMA (Time Division).
A band is given to each subscriber device by dividing it into time slots by a multiple access method and allocating the time slots so as not to overlap among the subscriber devices by using a transmission permission signal. The subscriber unit temporarily stores the data when it is sent from the subscriber. Then, if there is data to be sent, valid data is sent to the assigned time slot, and if not, invalid data is sent. Also, the subscriber device notifies the station side device of the amount of data stored in the buffer (hereinafter, buffer storage amount) using the congestion notification slot.

Next, FIG. 7 showing the operation of the congestion detection method will be described. It is assumed that data transmission starts at time t0. ΔT_up is a band update period, and when congestion occurs in the subscriber device, the station device reallocates the time slot in this period. Although the same as one frame is shown in the figure for the sake of explanation, it need not be so. ΔT_up
Is also a band monitoring cycle, and the station side device receives the buffer storage amount notification from the subscriber device in this cycle. It is assumed that the station side device starts monitoring the bandwidth of the subscriber device at time t0.
Here, if congestion occurs in the subscriber devices 5a and 5c at time t1, the buffer accumulation amount is sent to the station side device using the congestion notification slot. The congestion detection unit of the station side device starts detecting congestion at time t2, and the congestion detection time t_det
Then, it is determined that the subscriber device is congested. By the next time t3, the station side device calculates the bandwidth required for the subscriber devices 5a and 5c based on the notified buffer storage amount, and
At 3, the time slot allocation is actually increased. The response time T_res = t3−t1 from the occurrence of congestion until the allocation of time slots increases takes two bandwidth update cycles. Also, when congestion is recovered after that, the time slot allocation is reduced by the same method. Therefore, the response time requires two band update cycles.

Next, FIG. 8 showing a method of calculating the allocated bandwidth will be described. It is assumed that congestion occurs in the subscriber devices 5a and 5c at time t1 and 10 pieces of data are input to the buffer. Since the allocated bandwidth of the subscriber unit at time t1 is 0, valid data begins to accumulate in the buffer of the subscriber unit. Since the buffer storage amount of the subscriber device at time t1 is 0, the congestion detection unit calculates the bandwidth allocated at time t2 to be 0. The buffer storage amount increases to 10 from the time t1 to the time t2. At time t2, the bandwidth allocating unit determines that the subscriber unit 5
The bandwidth calculated at time t1 is allocated to a and 5c. Since the buffer storage amount at time t2 is 10, the bandwidth allocated at time t3 is calculated as 10. The buffer storage amount increases to 20 from time t2 to time t3. At time t3, the band allocation unit allocates the band calculated at time t2 to the subscriber devices 5a and 5c. After that, the same process is repeated, and when the congestion is recovered at time t8, the valid data accumulated in the buffer is swept at time t10, and the allocated bandwidth is restored at time t11. At this time, the amount of valid data stored in the buffer fluctuates up and down, and the allocated bandwidth of the subscriber device fluctuates up and down accordingly. Further, since the subscriber unit stores data sent from the subscriber until the bandwidth is updated, the buffer length corresponding to the response time is required.

[0006]

In the conventional method, when congestion occurs in the subscriber device, the allocated bandwidth increases after two bandwidth update cycles, and when the congestion recovers, the bandwidth update cycle becomes three.
Control delay occurs such that the allocated bandwidth decreases after that. In addition, since the allocated bandwidth of the subscriber device fluctuates up and down, the buffer length that allows for it is necessary. Therefore, the present invention mainly aims to solve such a problem.

[0007]

A communication system according to the present invention transmits data to a station side device for allocating a communication band and the station side device according to the communication band assigned by the station side device. A plurality of subscriber devices, each subscriber device having a data buffer, transmitting buffer storage amount information indicating the buffer storage amount of each data buffer to the station device, and the station side device. A communication system for updating the allocation of a communication band to each subscriber device at a predetermined band update cycle based on the buffer storage amount information transmitted from each subscriber device, wherein each subscriber device has a band update cycle. In a shorter cycle, the buffer storage amount information is transmitted to the station side apparatus at least once in each band update cycle, and the station side apparatus is a cycle shorter than the band update cycle than each subscriber apparatus. , It receives at least one or more buffer fullness information in each bandwidth update cycle, and updates the allocation of communication bands to each subscriber unit based on the buffer fullness information received from each subscriber unit.

The station side device predicts the buffer storage amount of each subscriber device at the time of the next update based on the buffer storage amount information received from each subscriber device, and predicts the buffer storage amount of each subscriber device. The communication band allocation to each subscriber device is updated based on the value.

The station side device receives the buffer storage amount information from each subscriber device a plurality of times in each band update period in a cycle shorter than the band update period, and receives a plurality of buffer storage amounts from each subscriber device. Based on the information, the buffer storage amount of each subscriber device at the time of the next update is predicted, and the allocation of the communication band to each subscriber device is updated based on the predicted value of the buffer storage amount of each subscriber device. And

The station side device allocates a communication band corresponding to the buffer storage amount shown in the latest buffer storage amount information of each subscriber device to each subscriber device.

A communication band management method according to the present invention has a station side device for allocating a communication band and a data buffer, and stores data to the station side device in accordance with the communication band assigned by the station side device. In a communication system having a plurality of subscriber devices for transmission, each subscriber device is caused to transmit buffer storage amount information indicating a buffer storage amount of each data buffer to the station device, and the station side device, A communication band management method for updating the allocation of a communication band to each subscriber device at a predetermined band update cycle based on the buffer storage amount information transmitted from each subscriber device, and updating the band to each subscriber device. In a cycle shorter than the cycle, the buffer storage amount information is transmitted to the station side apparatus at least once in each band update cycle, and the station side apparatus is shorter than the band update cycle. In each period, the buffer storage amount information from each subscriber device is received at least once in each band update cycle, and the allocation of the communication band to each subscriber device is updated based on the buffer storage amount information from each subscriber device. It is characterized by

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiment 1. FIG. 1 is a diagram showing the configuration of the communication system according to the present embodiment, which is similar to the conventional technique. FIG. 3 is a diagram showing the operation of the communication system according to the present embodiment, which will be described. This is different from the conventional operation in that there are a plurality of congestion notification slots (buffer storage amount information) used by the subscriber device to notify the station device of the buffer storage amount during each time. Others are the same as the conventional operation. Next, the congestion detection method will be described with reference to FIG. Data is transmitted at time t
Suppose that it starts from 0. ΔT_up is a band update cycle, and when congestion occurs in the subscriber device, the station device reallocates a time slot (communication band) in this cycle.
Although the same as one frame is shown in the figure for the sake of explanation, it need not be so. ΔT_mon is a band monitoring cycle, and the station side apparatus receives the buffer storage amount notification from the subscriber apparatus in this cycle. ΔT_mon is made shorter than ΔT_up. Here, ΔT_up is made twice as large as ΔT_mon.

It is assumed that the station side device starts monitoring the bandwidth of the subscriber device at time t0. Here, if congestion occurs in the subscriber devices 5a and 5c at time t1, the buffer accumulation amount is sent to the station side device using the congestion notification slot. The congestion detection unit of the station side device starts the detection of congestion at t1 ′ before time t2, and determines that congestion is occurring at time t_det before time t2. By the next time t2, the station side device determines the subscriber device 5 based on the notified buffer storage amount.
The bandwidths required for a and 5c are calculated, and the time slot allocation is actually increased at time t2. Response time T_r from the occurrence of congestion until the time slot allocation increases
es = t2-t1 is the same as the band update period. In addition,
When a plurality of congestion notification slots are received by the time t_det at the time of congestion detection after the last bandwidth update time t1, the station side device, based on the received plurality of congestion notification slots,
The buffer storage amount of the data buffer of each subscriber device is predicted at the next band update time t2, and the required bandwidth is calculated based on the predicted value of the buffer storage amount of each subscriber device. As another method, the same amount of communication bandwidth as the buffer accumulated amount shown in the latest congestion notification slot among the congestion notification slots received by the time t_det at the time of congestion detection since the time t1 of the last bandwidth update is allocated. You may
Also, when congestion is recovered after that, the time slot allocation is reduced by the same method. Therefore, the response time is the same as the bandwidth update period.

Next, a specific example of calculating the allocated bandwidth will be described with reference to FIG. It is assumed that congestion occurs in the subscriber devices 5a and 5c at time t1 and 10 pieces of data are input to the buffer. Since the allocated bandwidth of the subscriber unit at time t1 is 0, valid data begins to accumulate in the buffer of the subscriber unit. Since the buffer storage amount of the subscriber device at time t1 is 0 and the buffer storage amount at time t1 ′ is 5, the congestion detection unit calculates the bandwidth allocated at time t2 to be 10. The buffer accumulation amount is 10 between the time t1 and the time t2.
Increase. At time t2, the bandwidth allocating unit causes the subscriber devices 5a and 5
The bandwidth calculated at time t1 'is assigned to c. Since the buffer storage amount at time t2 is 10 and the buffer storage amount at time t2 ′ is 10, the bandwidth allocated at time t3 is calculated as 10. From the time t2 to the time t3, the buffer accumulation amount remains unchanged at 10. Time t
In 3, the band allocation unit allocates the band calculated at time t2 ′ to the subscriber devices 5a and 5c. After that, the same process is repeated, and when the congestion is recovered at time t8, the valid data accumulated in the buffer is swept at time t9, and the allocated bandwidth is restored at the same time t9. At this time, the amount of valid data stored in the buffer does not fluctuate vertically, and the allocated bandwidth of the subscriber device does not fluctuate vertically either. Therefore, the length of the buffer of each subscriber device can be shortened as compared with the conventional one.

Although the communication system according to the present invention has been described in the first embodiment, the communication band management method according to the present invention can be realized by the operation procedure shown in the first embodiment.

The characteristics of the communication system shown in the first embodiment will be reproduced below.

In the communication system according to the first embodiment, in the point-to-multipoint communication, the bandwidth monitoring period, which is a period in which the station side device monitors the buffer accumulation amount notified from the subscriber device, It is characterized in that the bandwidth is shorter than the bandwidth update cycle, which is the cycle of reallocating the bandwidth, and the bandwidth is reallocated based on the buffer storage amount notified in the bandwidth monitoring cycle.

In the point-to-multipoint communication, the communication system according to the first embodiment provides a plurality of bandwidth monitoring cycles in the bandwidth updating cycle, and notifies the plurality of bandwidth monitoring cycles immediately before the bandwidth updating cycle. It is characterized in that the amount of data stored in the buffer of the subscriber device is estimated by the bandwidth update period based on the buffer storage amount of 1 and is allocated in the bandwidth update period.

In the communication system according to the first embodiment, in point-to-multipoint communication, one bandwidth monitoring cycle is provided in the bandwidth update cycle, and the buffer accumulation amount notified in the bandwidth monitoring cycle is immediately after the bandwidth update cycle. It is characterized in that it is assigned in the update cycle.

[0020]

According to the present invention, the response time from the occurrence of congestion in the subscriber device or the elimination of the congestion to the update of the allocation of the communication band can be significantly shortened as compared with the conventional method. It is possible to dynamically perform effective bandwidth update matching the congestion state of the device.

Further, according to the present invention, since the buffer storage amount does not fluctuate up and down when congestion occurs in the subscriber device or when the congestion is resolved, the size of the data buffer of each subscriber device can be reduced to the conventional one. In comparison, the size can be significantly reduced, and the hardware resources can be saved.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a communication system according to a first embodiment.

FIG. 2 is a diagram illustrating terms and symbols.

FIG. 3 is a diagram showing an operation of the uplink communication system according to the first embodiment.

FIG. 4 is a diagram showing a congestion detection method according to the first embodiment.

FIG. 5 is a diagram showing a method of calculating an allocated bandwidth according to the first embodiment.

FIG. 6 is a diagram showing an operation of a conventional uplink communication system.

FIG. 7 is a diagram showing a conventional congestion detection method.

FIG. 8 is a diagram showing a conventional method of calculating an allocated bandwidth.

[Explanation of symbols]

1 station side device, 2 congestion detection unit, 3 band allocation unit, 4
Multiple brancher, 5 subscriber units, 6 buffers, 7 time slots, 8 congestion notification slots.

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Kazumi Oguchi             2-3 2-3 Marunouchi, Chiyoda-ku, Tokyo             Inside Ryo Electric Co., Ltd. F term (reference) 5K028 AA11 CC05 LL11 MM12 SS24                 5K030 GA05 GA13 JA07 JL08 LC11                 5K033 AA05 CB06 DB16 EA03

Claims (5)

[Claims] 1. A station-side device that allocates a communication band, and a plurality of subscriber devices that transmit data to the station-side device in accordance with the communication band allocated by the station-side device. The client device has a data buffer, and transmits buffer storage amount information indicating the buffer storage amount of each data buffer to the station device, and the station side device transmits the buffer storage amount transmitted from each subscriber device. A communication system that updates the allocation of a communication band to each subscriber device based on information in a predetermined band update period, wherein each subscriber device has a period shorter than the band update period and at least one The buffer storage amount information is transmitted to the station side device at least once, and the station side device transmits at least once in each band update cycle in a cycle shorter than the band update cycle from each subscriber device. A communication system characterized by receiving the above-mentioned buffer storage amount information and updating the allocation of the communication band to each subscriber device based on the buffer storage amount information received from each subscriber device. 2. The station side device predicts the buffer storage amount of each subscriber device at the time of the next update, based on the buffer storage amount information received from each subscriber device, and calculates the buffer storage amount of each subscriber device. The communication system according to claim 1, wherein the allocation of the communication band to each subscriber device is updated based on the predicted value of. 3. The station-side device receives buffer accumulation amount information from each subscriber device a plurality of times in each band update period at a period shorter than the band update period, and a plurality of buffers received from each subscriber device are received. Predict the buffer storage amount of each subscriber device at the time of the next update based on the storage amount information, and update the communication band allocation to each subscriber device based on the estimated buffer storage amount of each subscriber device. The communication system according to claim 1, wherein: 4. The station side device allocates to each subscriber device a communication band corresponding to the buffer storage amount shown in the latest buffer storage amount information of each subscriber device. The communication system according to. 5. A station side device for allocating a communication band, and a plurality of subscriber devices having a data buffer and transmitting data to the station side device according to the communication band allocated by the station side device. In a communication system having, each subscriber device is caused to transmit buffer storage amount information indicating the buffer storage amount of each data buffer to the station device, and the station device is transmitted from each subscriber device. A communication band management method for updating the allocation of a communication band to each subscriber device at a predetermined band update period based on the buffer accumulation amount information, wherein each subscriber device is provided with a band shorter than the band update period. The buffer storage amount information is transmitted to the station side device at least once or more in the update period, and the station side device is set to perform a cycle shorter than the band update period in each band update period. A communication band characterized by receiving the buffer storage amount information from each subscriber device at least once and updating the allocation of the communication band to each subscriber device based on the buffer storage amount information from each subscriber device. Management method.