JPH06311172A - Access controller - Google Patents

Abstract

PURPOSE:To keep the fairness of an access by receiving transmission interval information of the node from downstream at the time of the congestion of a transmission line, saving the transmission of its own node at the time of judging that its own node to transmit more than normal and working directly upon an adjacent node without lowering transmission efficiency. CONSTITUTION:When normal data sending is generated from an access controller 1 to a transmission line 2, the free state of a cell on a transmission line 2a is checked from a free state display part on a cell header and if the cell is free, it is sent by mounting data. On the other hand, a transmission interval measuring part 7 always measures an interval of sending the cell, successively calculates it as a transmission interval average value and holds a latest transmission interval average value. A transmission monitoring part 5 monitors a transmission cue 6 and sends the latest transmission interval average value data to an informing part 8 when the number of transmission waiting cells reaches a threshold value. The informing part 8 informs the pieces of data to an upstream node. A comparing part 9 compares an average transmission interval time with the average transmission time of its own node and at the time of sending at short intervals, a control part 10 is controlled to transmit at fixed intervals.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an access control device for accessing a transmission line of a node in a communication network system in which a plurality of access nodes are connected to a reverse transmission line. .

[0002]

2. Description of the Related Art FIG. 7 shows, for example, Japanese Patent Laid-Open No. 3-268542.
In the conventional packet transfer regulation method shown in No. 1, the transmission interval is controlled in the upstream node by regulating the number of packets per interval for transmitting a plurality of reference packets with the upstream node. In FIG. 7, 1
05 is a reference packet transmitted and received between packet switching nodes,
Reference numeral 101 is a reference packet transmitting means for transmitting the reference packet 105 to / from another packet switching node connected to the packet switching node, and 102 is a reference packet receiving means for receiving and processing the reference packet from the other packet switching node. . Reference numeral 104 is a reference packet transmission interval control means for controlling the transmission interval of the reference packet, and 103 is a reference packet reception interval, and regulates the number of communication packet data 106 sent to other packet switching nodes to a predetermined number or less. It is a means for controlling the number of transmitted packets.

Next, the operation of this device will be described. For example, in a transmission path sending section toward a certain packet switching node, when the number of packet data staying increases or the state progresses and a congestion state occurs, for example, each packet switching node from the preceding stage of the packet switching node The control by the configuration of FIG. 7 provided on the input side is performed as follows. That is, the reference packet transmission interval control means 104 controls the reference packet transmission means 101 so as to widen the transmission interval of the reference packet 105 to be transmitted to the preceding packet switching node. As a result, the following control is performed in the constituent portion of FIG. 7 in the packet switching node at the preceding stage. The transmission packet number control means 103 regulates the communication packet data 106 transmitted per reception interval of the reference packet 105 so as to be a predetermined number or less, but the reception interval of the reference packet 105 is widened as described above. As a result, the number of packets that can be transmitted in the meantime is determined, and as a result, the number of communication packet data 106 transmitted to the transmission path 107 per unit time is reduced.

As another conventional example, there is a packet transfer restriction system shown in FIG. 8, for example, Japanese Patent Laid-Open No. 2-209043. This is to avoid congestion by reducing the transmission interval when the traffic is small and increasing the transmission interval when the traffic is large to suppress the traffic flowing into the network. This operation is as follows. It is assumed that the transmission-side apparatus 110 is set to be able to continuously transmit to the network 120 in information frame units per unit time, and the number of frames is 5, for example. 4 and 0 are set in the window upper limit register 111 and the window lower limit register 112, respectively. These values will be updated as the transmission frame is updated. When the traffic state determination unit 115 determines that the traffic is in a congestion state, the transmission interval timer value determination unit 114 increases the timer value and increases the value of the transmission interval timer value register 113. Thus, the time during which the frame is sent will be extended.

[0005]

In the conventional data transmission method to the transmission line, the reference packet is transmitted to the preceding node even in the normal state where no congestion occurs, so that the transmission line utilization efficiency is improved. There is a problem that There is also a problem that the reference packet interval is unilaterally opened when the congestion occurs, so that the situation of the own switching node is ignored. On the other hand, in other conventional examples, the value of the interval timer is changed to specify the time interval, but even if it is effective on a low-speed transmission line, this method does not allow detailed congestion control in a high-speed transmission system. Is.

The present invention has been made to solve the above problems. In a communication network system in which a plurality of access nodes are connected to a double transmission path in the reverse direction, the transmission path can be transmitted even when the transmission path is congested. An object of the present invention is to obtain an access control device capable of imparting fair access to a transmission line of each node without lowering efficiency.

[0007]

The access control device according to the present invention is required in a communication network in which a reverse double transmission line is connected and each access node cyclically transmits and receives cells of fixed length in the transmission line. According to the transmission status notifying means for notifying the upstream node of the transmission interval information of the own node, the above transmission interval information sent from the downstream node, and the transmission interval value comparison for comparing the transmission interval information of the own node As a result of this comparison, there is provided a transmission control means for restricting the transmission to the transmission path of the own node, at least when the transmission interval value of the own node is shorter than the transmission interval value from the downstream by a prescribed amount or more. Further, the access control device of claim 2 further selects the congestion level from n (n is a natural number) stages as the upstream transmission interval information in the invention of claim 1, and the above number and the transmission interval from the downstream node. The transmission to the transmission line of the own node is regulated based on the congestion level from the information.

[0008]

The access control apparatus of the present invention receives the transmission interval information of the node from the downstream when the transmission line is congested, and when it is determined that the own node is transmitting more than a certain specified value, Try to suppress the transmission of. In the access control device according to the second aspect, the value of the interval information is leveled and simplified, and transmission / reception and comparison are further simplified.

[0009]

EXAMPLES Example 1. FIG. 1 is a block diagram of an access control device in a first embodiment of the present invention. In FIG.
1 is an access control device, 2a and 2b are transmission paths, 5 is a transmission monitoring unit, 6 is a transmission queue, 7 is a transmission interval measuring unit, 8 is a transmission state notifying unit, 9 is a transmission interval value comparing unit, and 10 is transmission control. It is a department. A reception processing unit that processes cells received from the transmission path 2a is omitted from this configuration diagram. Further, in the figure, a configuration is shown in which data is transmitted to the transmission path 2a and transmission interval information is placed in cells on the transmission path 2b and the upstream node is notified, but the operation is the same for the other configurations. Omitted.

FIG. 2 shows the positioning of the access device in the communication network system. In the figure, 2 is a transmission path, 100 is a node that accommodates terminals and the like, and that also accommodates an access control device and exchanges data with other nodes via the transmission path.

Next, the operation of this access control device will be described. When normal data transmission from the access control device 1 to the transmission line 2 occurs, the empty state of the cell on the transmission line 2 is checked from the empty state display section on the cell header, and if the cell is an empty cell, the data is transmitted. On the other hand, the transmission interval measuring unit 7 constantly measures the intervals at which cells are transmitted, successively calculates the transmission interval average value, and holds the latest transmission interval average value. In addition, the transmission monitoring unit 5 monitors the state of the transmission queue 6, and when the number of cells waiting to be transmitted reaches a certain set threshold value, the latest transmission interval average value data measured by the transmission interval measurement unit is displayed. It is sent to the transmission status notification unit 8. The transmission state notifying unit 8 puts the latest transmission interval average value data on the cells on the transmission line 2b in which the header transmission interval average value is not inserted, and notifies the upstream node.

In the transmission interval value comparison unit 9 of the upstream node, this transmission average interval time is compared with the transmission average time of its own node, and if the transmission is performed at a short interval of a certain specific ratio, the transmission control unit 10 The control is performed so that the data is transmitted at a constant interval. In this way, for example, the transmission efficiency is not lowered because the transmission interval value is added to the cell header and transmitted only when congestion occurs. Further, when the transmission interval value is received from the downstream side, the transmission control can be performed in consideration of the number of transmission cells of the own node and the degree of importance, so that rigid transmission suppression does not occur and flexible operation becomes possible.

Example 2. A second embodiment of the present invention will be described. FIGS. 3, 4 and 5 are diagrams relating to the second embodiment of the present invention. FIG. 3 monitors the transmission queue state change of the access control device and displays the transmission interval value from the transmission interval measuring unit (7). It is the flowchart which showed the algorithm transmitted to an upstream node. FIG. 4 shows the relationship between the transmission queue, the transmission interval, and the threshold value which change with time, and is a diagram for supplementary explanation of FIG. FIG. 5 shows a table for converting into the transmission interval level in order to reduce the information amount of the measured transmission interval value.

In FIG. 3, in step S1, a change in the status of the transmission queue is monitored. If there is a change, it is compared with the threshold value 1 (TH1) in the next step S2. If there is no change, the process loops in step S1. Next, in step S2, the transmission queue value is compared with the threshold 1 (TH1), and the transmission queue value is t _{1 in} FIG.
If it becomes TH1 or more as at time, the value of the average transmission interval value (Sg) at the time of stop is held in step S3, and TH
If it is 1 or less, the process returns to S1 without any processing.

Next, at step S4, as shown at time t ₂ in FIG. 4, it is compared with the threshold value 2 (TH2), and if it is equal to or more than TH2, the transmission interval value is converted into the transmission interval level (Sgr),
The transmission interval level (Sgr) is transmitted on the cell header on the transmission path. Further, in the case of TH2 or less, the transmission is stopped if the transmission interval level (Sgr) is being transmitted, and if not being transmitted, no processing is performed. The method of converting the average transmission interval value (Sg) into the transmission interval level (Sgr) is as shown in FIG.
A possible value of the average transmission interval value (Sg) is divided into blocks, and the block number corresponding to the block is set as the transmission interval level (Sgr).

In FIG. 5, n = as described in FIG. 3, for example.
Suppose there are 3 levels. That is, until TH1 is reached, there is no processing level at the transmission interval level 1, and there is no regulation for transmission. The transmission interval level becomes 2 between the transmission queues TH1 and TH2, and this is transmitted upstream. Upstream, this transmission interval level 2 is compared with the transmission interval level in the table of the own node. For example, when the own node is 1, the own node transmission regulation is performed. Instead of directly monitoring the number of the transmission queues 6 in FIG. 1, only the cells transmitted per unit time (that is, passing through the transmission queue exit) may be input and the transmission interval may be counted.

Embodiment 3. A third embodiment of the present invention will be described. FIG. 6 shows the configuration of the transmission interval value comparison unit 9 of the access control unit of this embodiment. In the figure, 20 is a transmission interval level value which is the transmission interval information from the downstream received from the transmission path 2b, and 21 is the transmission interval measuring unit 7 of the own node.
It is an average transmission interval level value that is the transmission interval information from. Reference numeral 22 is a register that holds the received transmission interval level value 20, 23 is a register that holds the transmission interval level value of the own node, and 24 is a level down unit that lowers the received transmission interval level value 21 by m levels. Reference numeral 25 is a comparator for comparing the level values from the level down unit 24 and the register 22, and 26 is a 1 / k down control unit which sets the reservation information in the empty cells once every k times and sends the reservation information to the downstream node. is there.

Next, the operation will be described. The transmission interval level value, which is the transmission interval information put on the transmission path 2b from the congestion node, is received by the upstream node, and the received transmission interval level value and the average transmission interval level value of the own node and the comparator 2
Compared in 5. The average transmission interval level value of the own node is m
If the transmission interval level value that has been lowered by the level is smaller, the following transmission control is performed. That is, once in k times, the reservation information is set in the empty cell and is flown to the downstream node so that the congested node can access it.
You can avoid congestion.

[0019]

As described above, according to the present invention, the transmission state notifying means for outputting the interval information to the upstream node, the interval value comparing means for the information from the network and the interval information of the own node, and the transmission for restricting the transmission. Since the control means is provided, there is an effect that it is possible to directly regulate other adjacent nodes with good transmission efficiency, and to perform access control in which the peculiarity of each node can be considered. Further, according to the invention of claim 2, since the interval information is expressed at a simple level, there is an effect that similar regulation can be performed even if the circuit scale is small.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of an access control device according to an embodiment of the present invention.

FIG. 2 is a system diagram showing the positioning of the present access device in the system.

FIG. 3 is a flowchart showing a transmission interval control algorithm by transmission queue monitoring in an access control device according to another embodiment of the present invention.

FIG. 4 is a diagram showing a relationship between a transmission queue and a threshold of an access control device according to another embodiment of the present invention.

FIG. 5 is a diagram showing a table for converting a transmission interval value into a transmission interval level.

FIG. 6 is a configuration diagram showing a part of a transmission interval comparison unit and a transmission control unit of an access control apparatus according to still another embodiment of the present invention.

FIG. 7 is a configuration diagram of a packet switching node in a conventional packet communication network.

FIG. 8 is a block diagram of a transmission side device of another conventional frame transmission system.

[Explanation of symbols]

 1 access control device 2a, 2b transmission line 5 transmission monitoring unit 7 transmission interval measuring unit 8 transmission status notifying unit 9 transmission interval value comparing unit 10 transmission control unit 22, 23 register 24 level down unit 25 comparator 26 1 / k down control Department

Claims (2)

[Claims] 1. In a communication network in which each access node is connected by a reverse double transmission path and cyclically transmits and receives cells of a fixed length in the transmission path, the transmission interval information of its own node is transmitted to an upstream node if necessary. To the transmission status notification means, the transmission interval value comparison means for comparing the transmission interval information from the downstream node, and the transmission interval information of the own node, as a result of the comparison, at least the transmission interval value of the own node is An access control device comprising: a transmission control unit that regulates transmission to a transmission path of a self node when the interval is shorter than a transmission interval value from downstream by a prescribed value or more. 2. As the upstream transmission interval information, a congestion level is selected from n stages with an arbitrary natural number n, and the transmission of its own node is performed based on the above number from the downstream node and the congestion level from the transmission interval information. The access control device according to claim 1, wherein transmission to a road is restricted.