JP3461459B2 - Packet buffer circuit - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention
The present invention relates to a packet buffer circuit mounted in a subscriber device that communicates while presenting a necessary bandwidth capacity and securing bandwidth allocation for the transmission system that shares the bandwidth of one transmission path.

[0002]

2. Description of the Related Art In a band sharing system of a time division multi-access system, a plurality of subscribers are connected to one station device, and in a communication from a subscriber device to a station device using a shared band, a subscriber is connected. It is a normal operation to output a band allocation request from the subscriber device, the station device receives the request, allocates the band, and the subscriber device that receives the allocation outputs a packet. Also, as control of the station device, even if a subscriber device requests bandwidth allocation and that subscriber device completes transmission of the packet, the station device will be the last device unless another subscriber device requests bandwidth allocation. Generally, control is performed to continue bandwidth allocation to a subscriber device that has made a bandwidth allocation request.

By the way, when the second and third packets are received from the terminal during the transmission of the first packet and the other subscriber devices do not request the bandwidth allocation and the bandwidth allocation is continued, If the second and third packets are sent out immediately without taking the procedure of making a new bandwidth allocation request, the transmission efficiency is improved. Here, if an attempt is made to transmit a packet having a bandwidth larger than necessary in the last frame of the first packet transmission over the next frame following the preceding packet, another packet is transmitted in the next frame. When there is a band allocation request from the subscriber device, the station device allocates the band to the subscriber device for which the band allocation request has been made.

[0004]

However, as a result, the packet being transmitted is discarded on the receiving side and retransmitted, which causes a problem that the transmission efficiency is lowered. In order to enable effective use of a practically necessary and sufficient band in multipoint communication or multiconnection communication in which a plurality of virtual channel connections are set for one call, Japanese Patent Laid-Open No. 08-340336 is disclosed. (ATM
A bandwidth allocation method of a network is a bandwidth shared by a predetermined combination of virtual channel connections that make up a call in an ATM network that sets a plurality of virtual channel connections for one call. It is disclosed that the reserved shared band is allocated to each channel connection of the same combination in correspondence with the actual communication status of each channel connection under a predetermined allocation condition.

A band sharing circuit for collecting and outputting information cells of a plurality of input lines for each output line, and a transmission system including the band sharing circuit are disclosed in Japanese Patent Laid-Open No. 11-4.
No. 227 is disclosed. In the case of this publication, the difference between the amount of cells accumulated in the cell buffer circuit and the set threshold value is monitored, and the cell transmission is limited to the information source transmitting the information cell according to the monitoring result. The information source is provided with means for adjusting the cell amount of the information cells to be sent to the band sharing circuit.

[0006] However, these publications do not provide a solution to the above-mentioned conventional problem of preventing a decrease in transmission efficiency due to the fact that a packet being transmitted is discarded and retransmitted on the receiving side. It should be noted that examples of the approximation technique include Japanese Patent Laid-Open No. 10-145424 (information communication method) and Japanese Patent Laid-Open No. 10-336186 (bandwidth allocation circuit).

The present invention has been made in order to solve the above-mentioned conventional problems, and allocates more bandwidth than requested,
When a packet with a size that fits in the extra band is in the transmission buffer, the packet is sent out following the preceding packet, thereby avoiding packet retransmission due to interruption of band allocation during transmission of the second packet, and transmitting. An object is to provide a packet buffer circuit that can improve efficiency.

[0008]

In order to achieve the above object, a plurality of transmission buffer memories for storing a packet transmitted by a terminal for each packet and write / read control to the transmission buffer memory are performed, and The size of each packet written in the transmission buffer memory is recognized, the packet read from the transmission buffer memory is output to the packet transmission unit, and one packet is output by the terminal.
Than the packet transmission final frame request
When allocated, the packet that can be sent to the extra band
If the packet is in the send buffer memory above, its
A transmission buffer control unit for outputting a packet, and a band allocation control unit for monitoring the band allocation request of the terminal and the band allocated by the station device are provided. Therefore, when the bandwidth allocation control unit recognizes that the bandwidth of the transmission packet data size or more is allocated to the final transmission frame of one packet, the bandwidth allocation control unit obtains the capacity of the bandwidth that is allocated more than necessary and notifies the transmission buffer accordingly. Notifying the control unit, the transmission buffer control unit compares the packet sizes stored in the plurality of transmission buffer memories, determines the packets that can be transmitted in the band allocated more than necessary, and is given the packet transmission permission signal. During this period, a packet selected from a plurality of packets following the preceding packet is sent to the shared band, so that the bandwidth allocation is interrupted during the transmission of the second packet and the second sent packet is discarded. Therefore, the transmission rate can be improved.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a packet buffer circuit according to the present invention will be described below with reference to the drawings. FIG. 1 shows a first embodiment of a packet buffer circuit according to the present invention.
It is a block diagram which shows the structure of embodiment. In FIG. 1, the case where the transmission buffer memory 2 is composed of five transmission buffers of the first transmission buffer 21 to the fifth transmission buffer 25 will be described for convenience of explanation. The first transmission buffer 21 is a first-in / first-out buffer memory in which packets sent by a terminal (not shown in FIG. 1) received by the terminal interface unit 1 are written. Second transmission buffer 22 to fifth transmission buffer 2
5 is a similar buffer memory.

Under the control of the transmission buffer control unit 6, the selector 3 selects one packet output from the five transmission buffers of the first transmission buffer 21 to the fifth transmission buffer 25 and outputs it to the packet transmission unit 4. Have the function to The packet transmission unit 4 has a function of outputting the packet output by the selector 3 to the station device interface unit 5.
When the transmission buffer control unit 6 is notified by the terminal interface unit 1 that the packet sent by the terminal has arrived, the transmission buffer control unit 6 controls the plurality of transmission buffers 21 to 25 to write the packet into one transmission buffer for each packet.

Further, the transmission buffer control unit 6 stores the packet sizes written in the first transmission buffer 21 to the fifth transmission buffer 25, and when a transmission permission signal is given from the station device interface unit 5, It has a function of controlling the first to fifth transmission buffers 21 to 25 and the selector 3 so that the selector 3 outputs the packet data to the packet transmission unit 4. Bandwidth allocation control unit 7
When the transmission buffer control unit 6 notifies that the terminal has transmitted the packet, it calculates how many block band allocation requests should be made, and from the band allocation information received via the station device interface unit 5, It has a function to calculate how many blocks should be requested in each frame.

Next, regarding the operation of the first embodiment, the sequence diagram of FIG. 2, the frame configuration diagram of FIG. 3 and FIG.
This will be described with reference to the system configuration diagram of FIG. In the frame configuration shown in FIG. 3, one frame includes a downlink area Fd and an uplink area Fu.
Further, the upstream region Fu has a fixed band (first half) Fu1, a fixed band (second half) Fu2, a shared band (block “1”) Fu3, a shared band (block “2”) Fu.
4, a shared band (block “3”) Fu5 and a shared band (block “4”) Fu6 are included.

FIG. 4 is a communication system in which a plurality of terminals using the optical splitter 8 share a band of one transmission line, and the packet buffer circuit of the present invention is applied to the subscriber devices 9a to 9n. There is. Each subscriber device 9a-
A plurality of terminals 10a to 10n are connected to 9n. In FIG. 4, in order to simplify the description, each of the subscriber devices 9a-9
The state where one is connected to each of n is shown.

For the sake of explanation, the following conditions and parameters are set. In the subscriber devices 9a-9n of FIG.
Continuous 3 only from the terminal 10a connected to the subscriber device 9a
It is assumed that one packet is transmitted and that the packet is not transmitted from the terminal connected to the other subscriber device during that time. The frames of the station device 8 and the subscriber devices 9a to 9n have the frame structure shown in FIG. 3, and the shared band in the upstream band is 4 blocks. Size of first packet arriving at subscriber device 9a: 120 Size of second packet arriving at subscriber device 9a: 100 Size of third packet arriving at subscriber device 9a: Uplink sharing within 40 frames Band block size: 20

Further, it is assumed that the allocation of the uplink shared band of the station device 8 has the following rules. As for the allocation of the upstream shared band from the station device 8, one subscriber device is selected from the requested subscriber devices and the band is continuously allocated until the data transmission from the subscriber device is completed. . When the data transmission of one subscriber device is completed, the station device continues to allocate the band to the last requested subscriber device if there is no band allocation request from another subscriber device. However, when another subscriber device makes an upstream band allocation request, it cancels the band allocation to this subscriber device even during communication,
Start bandwidth allocation for the requested subscriber unit.

Under the above conditions and parameter settings and rules, the operation is as follows. First, the subscriber device 9a in FIG. 4 receives the first packet sent from the terminal 10a (time T1 in FIG. 2). The packet transmitted from this terminal 10a is received by the terminal interface unit 1 of FIG.
The transmission buffer control unit 6 is notified that the terminal interface unit 1 has received. The transmission buffer control unit 6 recognizes the states of the transmission buffer memory 2 including a plurality of transmission buffers, that is, the first transmission buffer 21 to the fifth transmission buffer 25.

The transmission buffer control unit 6 writes the received first packet in the first transmission buffer 21. At the same time, the bandwidth allocation control unit 7 is notified of the size of the first packet. The band allocation control unit 7 outputs a request for the required number of blocks of the uplink shared band to the station device interface unit 5 (step S1 in FIG. 2). In the first embodiment, the size of the first packet is “120” and the size of one shared band is “20” as in the above parameter setting. Six blocks are required, but one frame has a maximum of four blocks in the shared band, so four blocks are requested.

The station device interface section 5 transmits the information on the band request to the station device 8. The subscriber device 9a in FIG. 4 transmits the information of the band request to the station device 8 (frame N in FIG. 2).
O. 1). The station device 8 which has received the bandwidth allocation request of 4 blocks from the subscriber device 9a of FIG. 4 permits the bandwidth allocation of 4 blocks to the subscriber device 9a, and the subscriber device 9a
Bandwidth allocation information is sent to a. The band allocation information is the station device interface unit 5 in the subscriber device 9a.
And the band allocation information is transmitted to the band allocation control unit 7.

In the station device interface section 5, a packet transmission permission signal is generated from the band allocation information,
It is sent to the transmission buffer control unit 6 (step S in FIG. 2).
2). Upon receiving the band allocation information, the band allocation control unit 7 of FIG. 1 recognizes that 4 blocks of the shared band have been allocated, and calculates how many more blocks to request in order to transmit the first packet. To do. In the first embodiment, 4 blocks are allocated to the first request, and the remaining "40"("120"-"80"), so 2 blocks are requested.

The transmission buffer control unit 6 of FIG. 1, which has received the packet transmission permission signal, reads the first packet from the first transmission buffer 21 of the transmission buffer memory 2 while the transmission is permitted, and controls the selector 3. Then, the first packet data read out is sent to the packet sending unit 4.
In the first embodiment, only “80” of the total size “120” is read and sent to the packet sending unit 4. Frame No. It is assumed that the second and third packets arrive from the terminal 10a connected to the subscriber device 9a in FIG. 4 during 2 (time T2, time T3 in FIG. 2).

The respective packet sizes are "100" and "40". The transmission buffer control unit 6 of FIG.
Since the first packet is stored in the transmission buffer 21, the second packet is stored in the second transmission buffer 22 of the transmission buffer memory 2, and the third packet is stored in the third transmission buffer 23 of the transmission buffer memory 2. Control to do. The transmission buffer control unit 6 stores the second and third packet sizes. The two blocks of band allocation request information calculated by the band allocation control unit 7 and the first packet data sent to the packet sending unit 4 are output from the station device interface unit 5 to the station device 8.

The subscriber unit 9a of FIG. 4 receives the band allocation request information of two blocks and the first packet data from the station unit 8a.
(Frame No. 2 in FIG. 2). The station device 8 of FIG. 4 receives the first packet and also receives a bandwidth allocation request for two blocks. Here, if the station device 8 does not receive a bandwidth allocation request from another subscriber device, 2
Even if there is a bandwidth allocation request for only blocks, bandwidth allocation for 4 blocks is performed (step S3 in FIG. 2).

The station device 8 sends the next frame to the subscriber device 9a.
To 4 blocks of bandwidth allocation information is transmitted. The band allocation information is sent to the band allocation control unit 7 in FIG. 1 as in the previous frame. The band allocation control unit 7 that has received the band allocation information requests the transmission buffer control that there are 4 blocks allocated even though only 2 blocks are requested and that the extra allocated band is "40". Notify Part 6.

After transmitting the first packet, the transmission buffer controller 6 confirms the size of the second packet when recognizing that the free band of "40" is further allocated. In the first embodiment, the size of the second packet is “100”, and transmission is not possible with only the free band of “40”. The transmission buffer control unit 6 subsequently confirms the size of the third packet. In the first embodiment, the size of the third packet is “40”, and the packet can be transmitted in the free band. Transmission buffer control unit 6
Decides to send the third packet to the vacant band following the first packet (step S in FIG. 2).
4).

The transmission buffer control unit 6 that has received the packet transmission permission signal reads the first packet from the first transmission buffer 21 of the transmission buffer memory 2 while the transmission is permitted, and controls the selector to control the packet transmission unit. The first packet data read out is transmitted. After the transmission of the first packet is completed, the third packet is read from the third transmission buffer 23 of the transmission buffer memory 2, and
The selector 3 is switched to send the third packet data to the packet sending unit 4.

At the same time, the bandwidth allocation control unit 7
Output a bandwidth allocation request to send the second packet. In the first embodiment, since the second packet is "100", five shared band blocks are required to transmit all the packets, but one frame has a maximum of four shared band blocks. So request 4 blocks. The first and third packet data read from the transmission buffer memory 2 and the band allocation information output by the band allocation control unit 7 are transmitted to the station device 8 via the station device interface unit 5 (FIG. 2). Frame N
O. 3).

As described above, in the first embodiment, when a bandwidth more than the request is allocated to the final transmission frame of one packet, the extra bandwidth and the respective storage buffers stored in the plurality of transmission buffers are stored. By comparing the packet sizes, and if there is a packet that can be sent in the extra band, by outputting the packet (step S5 in FIG. 2), band allocation is interrupted during transmission of the second packet, and the second packet is sent. It is possible to avoid the retransmission that is performed because the packet sent to is discarded. Accordingly, the transmission rate can be improved.

Next, a second embodiment of the present invention will be described. FIG. 5 is a block diagram showing the configuration of the second embodiment. In the second embodiment, one transmission buffer memory 2 is divided into a plurality of blocks, and the transmission buffer control unit 6 writes each packet in a separate block,
It has a function of storing the address of the block and the packet size, reading each stored packet for each address, and transmitting the packet to the packet transmitting unit 4. Along with this, the selector 3 shown in FIG. 1 is omitted, and the transmission buffer control unit 6 also has the function of the selector 3.

[0029]

As described above, according to the present invention, in a communication system in which a plurality of terminals share a band of one transmission line, a required band capacity is presented, and communication is performed while ensuring band allocation for the band capacity. In the terminal device, the packet sent by the terminal in the subscriber device is stored in the transmission buffer memory for each packet, the transmission buffer memory is controlled by the transmission buffer control unit, and the size of the packet in the transmission buffer is stored. Since the bandwidth allocation control unit monitors the bandwidth information allocated from the station device to detect that there is more bandwidth allocation than requested and its size, it is possible to allocate more bandwidth than requested and If a packet with a size that fits within a certain bandwidth is in the send buffer, send that packet after the preceding packet , It is possible to avoid the retransmission of the packet according to the band allocation interruption during transmission the second packet, thus it is possible to improve the transmission efficiency.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a first embodiment of a packet buffer circuit according to the present invention.

FIG. 2 is a sequence diagram for explaining the operation of the first embodiment of the packet buffer circuit according to the present invention.

FIG. 3 is an explanatory diagram showing a frame structure applied to the first embodiment of the packet buffer circuit according to the present invention.

FIG. 4 is a structural explanatory diagram of a communication system in which a plurality of terminals share the band of one transmission line to which the first embodiment of the packet buffer circuit according to the present invention is applied.

FIG. 5 is a block diagram showing a configuration of a second embodiment of a packet buffer circuit according to the present invention.

[Explanation of symbols]

1 ... Terminal interface section, 2 ... Transmission buffer memory, 3 ... Selector, 4 ... Packet transmission section, 5 ... Station device interface section, 6 ... Transmission buffer control section, 7
...... Bandwidth allocation control unit, 8 ...... Station device, 9a to 9n ...
... subscriber device, 10a to 10n ... terminal, 21 ... first
Transmission buffer, 22 ... Second transmission buffer, 23 ... Third transmission buffer, 24 ... Fourth transmission buffer, 25 ...
Fifth send buffer.

─────────────────────────────────────────────────── ─── Continuation of the front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) H04L 12/00

Claims (6)

(57) [Claims] 1. A transmission line band is shared by a plurality of terminals.
The required transmission capacity is presented to the
Communication while securing bandwidth allocation from the station device
A packet buffer circuit implemented in the subscriber device
I, recognizing a plurality of transmission buffer memory for storing packets that the terminal transmits per packet, performs read / write control to the transmission buffer memory, and the size of each packet written in the transmission buffer memory And output the packet read from the transmission buffer memory to the packet sending unit ,
Final frame request for transmission of one packet by the terminal
When the band is allocated from the above station device,
Packets that can be sent to the extra bandwidth of
A packet buffer, comprising: a transmission buffer control unit that outputs the packet if it exists in the memory; and a band allocation control unit that monitors the band allocation request of the terminal and the band allocated from the station device. circuit. 2. The packet sending unit receives the packet read by the sending buffer control unit from a sending buffer memory composed of a plurality of sending buffers by switching with a selector. Packet buffer circuit. 3. The packet buffer circuit according to claim 1, wherein the transmission buffer memory is composed of one and is divided into a plurality of blocks. 4. The transmission buffer control unit writes the packet into each block of the transmission buffer memory separately, stores the address and packet size of the block, reads the packet, and sends it to the packet transmission unit. The packet buffer circuit according to claim 3, wherein 5. The transmission buffer control unit, upon being notified by the terminal interface unit that the packet transmitted by the terminal has arrived, controls the plurality of transmission buffers constituting the transmission buffer memory to packetize the packet. The packet buffer circuit according to claim 1, wherein one packet is written in each transmission buffer. 6. The terminal is a predetermined one of the subscriber units.
2. The packet buffer circuit according to claim 1, wherein three packets are continuously transmitted from only one terminal connected to one subscriber terminal, and no packet is transmitted from a terminal connected to another subscriber device during that period.