KR100389759B1 - Call Distribution Method in Remote Access Server - Google Patents

Abstract

The present invention distributes a call input to a remote access server (hereinafter referred to as 'RAS') to each network matching unit in consideration of channel capacity and failure of each network matching unit. It is about a method.

Among conventional call distribution methods in RAS, the round-robin method distributes calls evenly without considering the call processing capability of each network matching part and how many channels are currently available. Although there was a channel available in the network matching, there was a problem that call connection could be failed due to the distribution of a call in a network matching unit without an available channel.In the case of a call distribution method considering an available channel of the network matching, a call is distributed to a specific network matching unit. In case that the network matching unit reports its available channel information to the call distribution unit without recognizing that the failure has occurred, even if the call connection fails, the call distribution unit considers only the available channel information to distribute the call. There was a problem in that call distribution was not continued because the call matching was continuously performed.

The present invention calculates the available channel ratio of each network junction portion provided in the RAS to determine the order of call distribution and distribute the calls, while in the event of a failure in the network registration part, so as not to distribute the call a predetermined number of times to the network matching part. As a result, the call received in the RAS can be efficiently distributed.

Description

Call Distribution Method in Remote Access Server

The present invention relates to a call distribution method in a remote access server. In particular, a call input to a remote access server (hereinafter referred to as "RAS") is considered in consideration of a capacity and failure of each network matching unit. The present invention relates to a call distribution method in a RAS for efficiently distributing to each network matching unit.

In general, if a RAS is connected to the Internet, which allows remote computers to connect to each other using dial-up, X.25, or null modem cables, dial-up networking users can access the Internet through RAS. .

RAS also provides access to existing LAN environments through Dial-Up Networking. Computers dialed through RAS can run in the same environment as if they were directly connected to an existing LAN.

1 is a configuration block diagram for call distribution in the RAS.

The RAS includes a subscriber matching unit 100, a switch unit 200, and a network matching unit 300, 310, 320, 330 for distributing a call inputted to the subscriber station. The subscriber matching unit 100 is again connected with the call receiving unit 120. , Call processing manager 130, and call distribution unit 110.

The subscriber matching unit 100 receives a call input from an exchange (not shown) and distributes it to each network matching unit 300, 310, 320, 330 through the switch unit 200, and the call receiving unit 120 constituting the subscriber matching unit 100. ) Receives the call and transmits it to the call processing manager 130, and the call processing manager 130 collects information on which network (Internet network, packet network, etc.) the call is for to receive the service. The call distribution unit 110 receives the information from the call processing management unit 130 and selects a network matching unit interworking with the network required by the call from among the network matching units 300, 310, 320, and 330. The call is distributed to the network interface.

The switch unit 200 switches the call to the network matching unit 300, 310, 320, 330 to be the call distribution under the control of the call distribution unit 110, and the network matching unit 300, 310, 320, 330 serves to receive the service according to the request of the distributed call. Occupies the channel connected with the subscriber to allow the subscriber to receive service.

In the conventional call distribution method in such a RAS, a method of equally distributing a call input to the RAS to each network matching unit (Round-Robin method) and a call matching unit preferentially to a network matching unit having many available channels capable of processing a call There is a way to dispense.

However, since the round-robin method distributes calls evenly without considering the call processing capability of each network matching unit and how many channels are currently available, even though there are channels available in other network matching units, There was a problem that call connection could be failed because a call is distributed to a network matching unit that does not have an available channel, and the call distribution method considering available channels of the network matching unit has a problem that the call connection fails even when a call is distributed to a specific network matching unit. If the network matching unit does not recognize the fact that the failure has occurred and reports the available channel information to the call distribution unit, the call distribution unit distributes the call only considering the available channel information, and thus the call distribution unit continues to distribute the failed network matching unit. There was a problem that the call can not be processed.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and its object is to calculate the available channel ratio of each network matching unit provided in the RAS, determine the order of call distribution, distribute the calls, and prevent the network matching unit from failing. In this case, it is possible to efficiently distribute a call received to the RAS by not distributing the call a predetermined number of times to the network matching part.

1 is a configuration block diagram for call distribution within the RAS.

2 is a flow diagram illustrating a call distribution process within a RAS in accordance with the present invention.

3 is a call distribution table.

* Description of the symbols for the main parts of the drawings *

100: subscriber matching unit 110: call distribution unit

120: call receiving unit 130: call processing management unit

200: switch unit 300: first network matching unit

310: second network matching unit 320: third network matching unit

330: fourth network matching unit

A feature of the present invention for achieving the above object is a call distribution method in a remote access server for distributing a call input to a remote access server in a network matching unit provided in the remote access server. Calculating an available channel ratio of each network matching unit and determining a call distribution order of the network matching unit according to the available channel ratios; Checking whether the network matching unit receives the omission variable according to the call distribution order and determining whether the omission variable of the network matching unit is equal to the initial setting value of the omission variable; As a result of the determination, when the skipped variable is equal to the initial set value, distributing a call to the network matching unit and determining whether a failure occurs in the network matching unit; If it is determined that the failure does not occur in the network matching unit, setting a failure variable to the initial setting value, increasing the number of channels used in the network matching unit by one, and calculating and setting a new use channel ratio of the network matching unit; ; Determining whether the network matching unit is a last order network matching unit; If the network matching unit is not the last network matching unit, as a result of the determination, the process of repeating the process of selecting a network matching unit of the next rank, checking the omitted parameters of the selected network matching unit, distributing a call, and determining whether or not a failure occurs is performed. It is included.

Herein, the present invention also determines whether the network matching unit is the last priority network matching unit, and determines whether to continue to provide a service when the network matching unit is the last network matching unit. It is characterized by repeating the process of call distribution by calculating the available channel ratio of the network matching.

And, the present invention is characterized in that it further comprises the step of increasing the failure variable and the skipped variable when the failure occurs as a result of determining whether the failure occurs in the network matching.

Further, according to the present invention, if it is determined whether the omission variable of the network matching unit is equal to the initial setting value of the omission variable, when the omission variable is not the initial setting value, the network matching unit does not distribute a call to the network matching unit. It further comprises the step of reducing the omission variable of.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, various variables used in the present invention will be described.

The maximum number of receiving channels is the number of channels that each network matching unit can accommodate maximum, the maximum channel ratio is the ratio of the maximum number of receiving channels of each network matching unit to the sum of the maximum number of receiving channels of all network matching units, The number of channels used is the number of calls currently being distributed to each network matching unit and the number of calls being used is the ratio of the number of calls distributed to each network matching unit to the number of calls currently distributed to all network matching units. The available channel ratio is 'maximum channel ratio-used channel ratio'.

On the other hand, the failure variable means the number of times a failure occurs in the network matching part, and the skip variable refers to the number of times the call distribution is omitted in the network matching part. As it is counted down.

For example, among the four network matching units provided in the RAS, the maximum receiving channel number of the first network matching unit is 30, the maximum receiving channel number of the second network matching unit is 10, the maximum receiving channel number of the third network matching unit is 20, and 4, the maximum channel ratio of the first network matching unit is 0.3 (= 30 / (30 + 10 + 20 + 40)), the maximum channel ratio of the second network matching unit is 0.1 ( = 10 / (30 + 10 + 20 + 40)), the maximum channel ratio of the third network match is 0.2 (= 20 / (30 + 10 + 20 + 40)), and the maximum channel ratio of the fourth network match is 0.4 (= 40 / (30 + 10 + 20 + 40)). If the number of channels used by the first network matching unit is 9, the number of channels used by the second network matching unit is 2, the number of channels used by the third network matching unit is 5, and the number of channels used by the fourth network matching unit is 12, the first network matching unit is performed. The usage channel ratio of is 0.32 (= 9/28), the usage channel ratio of the second network matching portion is 0.07 (= 2/28), the usage channel ratio of the third network matching portion is 0.18 (= 5/28), The channel ratio used for the fourth network matching unit is 0.43 (= 12/28). The available channel ratio of the first network matching unit is -0.02 (= 0.3-0.32), the available channel ratio of the second network matching unit is 0.03 (= 0.1-0.07), and the available channel ratio of the third network matching unit is 0.02 (= 0.2-0.18), and the available channel ratio of the fourth network matching unit is -0.03 (= 0.4-0.43).

2 is a flowchart illustrating a call distribution process within a RAS according to the present invention.

First, the available channel ratio of each network matching unit is calculated (S21). In order to calculate the available channel ratio, it is necessary to first set or calculate the maximum number of acceptance channels, the maximum channel ratio, the number of use channels, and the use channel ratio as described above.

The call distribution unit has a table as shown in FIG. 3 to determine the priority when distributing a call to each network matching unit, and does not distribute a predetermined number of call distribution units to the network matching unit when a network matching unit has a failure. .

When the available channel ratio of each network matching unit is calculated in the process of S21, the call distribution order is determined according to the available channel ratio (S22). The relatively large available channel ratio means that there are a large number of extra available channels capable of call processing, so that priority is allocated according to the size of the available channel ratio to distribute the call to each network matching unit. For example, the available channel ratio of the first network matching unit is -0.02 among the four network matching units, the available channel ratio of the second network matching unit is 0.03, the available channel ratio of the third network matching unit is 0.02, and the available channel ratio of the fourth network matching unit is-. When 0.03, the call distribution sequence is 'second network matching part → third network matching part → first network matching part → fourth network matching part'. In this order, the call is distributed to each network matching unit.

Accordingly, when the call distribution order of each network matching unit is determined in the process of S22, the highest network matching unit is selected (S23). In the above example, since the available channel ratio of the second network matching unit is the largest, call distribution is made first with the second network matching unit.

When the highest priority network matching unit is selected in the process of S23, first, an omission variable of the corresponding network matching unit is checked (S24), and it is determined whether or not the omission variable of the network matching unit is an initial setting value of '0' (S25).

As a result of the determination, when the omission variable is '0', the call is distributed to the network matching unit (S26) and at the same time, the network matching unit checks whether or not a failure occurs by checking whether the call fails ( S27), it is determined whether a failure occurs in the network matching unit (S28).

As a result of determining whether a failure occurs in the process of S28, if it is determined that a failure has occurred, the failure variable and the skipped variable are increased (S33). If it is determined that the failure does not occur, the failure variable is set to '0' and The number of channels used by the summation unit is increased by one, and the set channel ratio of the network matching unit is set to the presently calculated current value (S29).

When the setting of the obstacle variable or the skipped variable is completed, it is determined whether the network matching unit is the last network matching unit (S30). As a result, when the network matching unit is the last network matching unit, it is determined whether to stop providing the service by RAS again (S34), and when the termination is completed, all call distribution processes are terminated together, but if the service is continuously provided Returning to the process of S21 to continue the call distribution according to the present invention.

However, as a result of determining whether the network matching unit is the last priority network matching unit in the process of S30, when the network matching unit is not the last network matching unit, the next network matching unit (the third network matching unit in the above-described example) is selected (S31). The process of returning to the call of the step S24 for checking the omission parameter of the network matching part is continued.

If the omission variable of the network matching unit is not '0' in the process of S25, the call matching unit is not distributed, but the omission variable of the network matching unit is reduced (S32), and the network matching unit is the last priority. The process of S30 determining whether or not the network matching unit is performed is performed.

Although the present invention has been described in detail only with respect to the above-described embodiments, it will be apparent to those skilled in the art that modifications or variations can be made within the spirit and scope of the present invention, and such modifications or changes are within the scope of the claims Will belong.

As described above, the present invention calculates the available channel ratio of each network matching unit provided in the RAS, determines the order of call distribution, and distributes calls, while a failure occurs in the network matching unit, a predetermined number of calls are made to the network matching unit. By not distributing, the call received by the RAS can be efficiently distributed.

Claims (4)

A call distribution method in a remote access server for distributing a call input to a remote access server to a network matching unit provided in the remote access server. Calculating an available channel ratio of each network matching unit of the remote access server and determining a call distribution order of the network matching unit according to the available channel ratios; Checking whether the network matching unit receives the omission variable according to the call distribution order and determining whether the omission variable of the network matching unit is equal to the initial setting value of the omission variable; As a result of the determination, when the skipped variable is equal to the initial set value, distributing a call to the network matching unit and determining whether a failure occurs in the network matching unit; If it is determined that the failure does not occur in the network matching unit, setting a failure variable to the initial setting value, increasing the number of channels used in the network matching unit by one, and calculating and setting a new use channel ratio of the network matching unit; ; Determining whether the network matching unit is a last order network matching unit; If the network matching unit is not the last network matching unit, as a result of the determination, the process of repeating the process of selecting a network matching unit of the next rank, checking the omitted parameters of the selected network matching unit, distributing a call, and determining whether or not a failure occurs is performed. Call distribution method in a remote access server comprising a. The method of claim 1, As a result of determining whether the network matching unit is the last priority network matching unit, it is determined whether to continue to provide a service when the network matching unit is the last network matching unit, and when the service is continuously provided, an available channel of each network matching unit constituting the remote access server. A call distribution method in a remote access server, comprising repeating a call distribution by calculating a ratio. The method of claim 1, And as a result of determining whether a failure has occurred in the network matching unit, increasing a failure variable and an omitted variable when the failure occurs. The method of claim 1, As a result of determining whether the omission variable of the network matching unit is equal to the initial setting value of the omission variable, when the omission variable is not the initial setting value, the omission variable of the network matching unit is reduced without distributing a call to the network matching unit. And further comprising the step of: making a call distribution method at the remote access server.