KR20020052567A - Gateway and Optimal Resource Allocation of the Gateway - Google Patents

Abstract

PURPOSE: A gateway between different kinds of networks for the improvement of communication speed and a method for allocating resources thereby are provided to offer an automatic bandwidth control method for an Internet traffic change in a communication processing system to continually supply virtual access service to Internet service providers on the basis of frame transmission, in the case of providing connection-oriented service in a communication system. CONSTITUTION: If data are inputted to a link layer drive task queue and setup for a subscriber's input call is completed, a link layer drive task determines a link control routine(ToLCP) or a frame receiving routine(CMD_FRM_RCVD). If a PPP command is CMD_FRM_SND to transmit Ack/Nak/Reject packets or IP packets to an LLD, the link layer drive task negotiates a logical channel with a WNAS while monitoring Internet traffics, and transmits frames to an associated channel(SendToPort). Then the link layer drive task calls a data transmitting routine in order to transmit data to an internal switch(SendDataToNCCB), determines a PPP frame or an MP frame to send data, and executes a data transmit-receive process for a basic channel.

Description

Gateway between heterogeneous networks and communication method for improving communication speed {Gateway and Optimal Resource Allocation of the Gateway}

The present invention relates to a method for automatically adjusting a communication bandwidth by monitoring a change in forwarded traffic in a system after establishing a channel connection to a communication subscriber of a communication processing system (or gateway) providing interworking function between different public networks.

In general, most PC communication users to date are connected to a telephone network or ISDN using a modem or network termination device, which is an analog-to / from-digital signal converter, and has a 1: 1 connection with a remote modem in the host. The service is available by.

In this case, PC communication users mainly use the file download (downloading) service from the host, and the transmission speed is a measure of the quality of service, and the Internet connection in the existing public network is connected to the ISP (Internet Service Provider) by circuit switching. Because of the connection, if a subscriber occupies the port for a long time, congestion of voice network may occur.

That is, until now, the line connection in the heterogeneous network interworking module in the communication processing system has been used regardless of the traffic until the connection is released through the given basic channel only. Due to the explosive increase in the use of the Internet, the conventional Internet connection is connected to the service provider in a circuit-switched manner until the connection is terminated after the connection is established. There is a problem that occurs.

And, there is a disadvantage that can not use the system resources to the maximum.

An object of the present invention for solving the above problems relates to a traffic monitoring method for providing an Internet-connected service using a packet handler and X.25 packet technology of the existing ISDN, communication by applying the existing packet transmission technology The present invention provides a method for automatically adjusting a bandwidth of Internet traffic changes in a communication processing system that provides a continuous virtual access service to an Internet service provider based on frame transmission when providing a connection type service in a system.

1 is a network diagram of a communication processing system to which the present invention is applied

2 is a flowchart of a link layer drive for bandwidth adjustment according to the present invention.

3 is a flowchart illustrating an internet bandwidth adjustment according to the present invention.

A heterogeneous inter-gateway system that improves communication speed by optimal resource allocation according to the present invention for achieving the above object is characterized by the public data network (PNAS) or the Internet (WNAS) and the X.25 standard protocol; A gateway system for providing data communication service to a data communication user connected to a general telephone network by interconnecting data communicated through a frame relay network (FNAS) or the like: An internal switch having a service processing board, connected to each of the connected existing networks in a standard TCP / IP manner, and responsible for relaying data traffic; A general telephone network access module having a telephone network matching board for negotiating trunk matching and subscriber modem and multiplexing data, and a telephone network service processing board for controlling an interface with the internal switch and processing a service; And a system management apparatus that manages the overall operation of the system and provides an optimum communication bandwidth by monitoring a change in the forwarded traffic in the system after establishing a channel connection to a communication subscriber.

An additional feature of heterogeneous inter-gateway systems for improving communication speed by optimal resource allocation in accordance with the present invention for achieving the above object is that the telephone network matching board is processed in European PCM data format, and various subscriber modems It is equipped with a trunk interface module that operates at 56kbps and supports protocols such as V.90 / V.34 / V.32bis and V.42 / V.42bis.

An additional feature of the heterogeneous network gateway system for improving communication speed by optimal resource allocation according to the present invention for achieving the above object is that the telephone network service processing board transmits outgoing subscriber information through the telephone network matching board. It assigns one channel among multiple subscriber modems, establishes a call path, performs smooth information transmission through the flow control function of subscriber data, and the PC communication user simultaneously accesses the general telephone network access module at a speed of 56kbps / Frame relay network / It is possible to search the database information connected to the Internet, and to deliver the received information to a designated user at high speed.

An additional feature of the heterogeneous inter-gateway gateway system for improving communication speed by optimal resource allocation according to the present invention for achieving the above object is that the telephone network service processing board is connected to the system management apparatus to serve a subscriber. When it is terminated, the network usage information and billing information is transmitted to the system management device, and the shape information, fault information, etc. of the currently operating system is periodically transmitted to the system management device.

An additional feature of the heterogeneous inter-gateway system for improving the communication speed by the optimal resource allocation according to the present invention for achieving the above object is that the telephone network service processing board is a real-time operating system to support the service of multiple subscribers It is to manage the resources required for communication with the transmit / receive task operating in.

According to another aspect of the present invention, there is provided a resource allocation method in a heterogeneous gateway system. ; A second step of allocating circuit resources of the second network to circuits belonging to the first network to allow connection between the networks; A third step of monitoring a communication speed of a line belonging to the first network; And a fourth step of increasing or decreasing the number of line resources of the second network allocated to the corresponding line if the communication speed of one of the lines belonging to the first network exceeds the threshold.

As a further feature of the present invention for achieving the above object, the second step is to maintain the fluid bandwidth sum between the Internet and the public telecommunication network at a continuous control interval.

In another additional aspect of the present invention for achieving the above object, the third step is to determine the traffic count of the telephone network subscriber in the public telecommunication network.

As another additional feature of the present invention for achieving the above object, the fourth step adjusts the bandwidth of the Internet according to the traffic count for the resource allocated in the first step, and the bandwidth is adjusted with the corresponding subscriber module of the public communication network. And at least one of a transmission path between the service controllers and a transmission path with the Internet.

The above object and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings by those skilled in the art.

First, the technical idea of the present invention will be briefly described. The present invention is based on the existing packet transmission technology. When providing a connected service in a communication system, the present invention provides a continuous virtual access service to an Internet service provider based on frame transmission. It is conceived that it can provide.If high bandwidth is needed during communication through logical channel in communication system, two channels are automatically connected in order according to the required bandwidth to provide maximum bandwidth. The two logical channel connections are automatically disconnected to provide data communication.

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

1 is an overall structural diagram of a communication processing system.

The communication processing system interconnects a general telephone network (11, TNAS), a public data network (12, PNAS) using the X.25 standard protocol, the Internet (13, WNAS), and a frame relay network (14, FNAS). Provide communication. The internal switch 15 (ESAS) is connected to the service processing boards 112, 122, 132, and 142 of various types of network matching modules in a standard TCP / IP manner, and plays a role of relaying data traffic.

The telephony network access subsystem (TNAS) 11 is responsible for the transmission of various modem connections and information provider data to PC users connected to the telephone network.

The TNAS is a telephone network access board (TNAB) 111 that handles trunk matching, negotiation with subscriber modems, and data multiplexing, and an interface between an ESAS and a telephone network service processing board (Tnas Service). Processing Board: TSPB, 112).

At this time, TNAB is a trunk interface module, processed in European PCM data format, operated with various subscriber modems and 56kbps, and using protocols such as V.90 / V.34 / V.32bis and V.42 / V.42bis. Support.

In addition, the TSPB 112 receives the outgoing subscriber information of the TNAB, allocates one channel among multiple subscriber modems, sets up a call path, and performs smooth information transmission through a flow control function of subscriber data. At the same time, it connects to the TNAS at 56kbps to retrieve database information connected to the packet network / frame relay network / internet and delivers the information received from the host to the designated user at high speed.

When the subscriber terminates the service, the TSPB 112 transmits network usage information and billing information to a local operation and management system (LOMS) 16 that is a system management device. In addition, TNAS periodically transmits the configuration information and fault information of the currently operating system to the system management device. The TSPB manages the resources required for communication with the transmit / receive task operating in the real-time operating system to support the service of multiple subscribers.

2A to 2C show a flowchart of a link layer drive task for controlling Internet traffic as a function for exchanging data generated in each task.

The protocol field of the packet inputted from the subscriber of the public network is examined and LCP, IPCP, and IP are classified and passed to the corresponding task. It is also used to deliver IP packets received from Internet protocols to the LLD.

First, data is input to the drive task queue (LLDQ) of the link layer in step S101, and when the setting of the subscriber's input call is completed (PPP command) in step S102, the link control routine (ToLCP) or the frame reception routine (CMD_FRM_RCVD) is executed. Decide

Here, CMD_UP / DOWN / OPEN proceeds to step S103 to post to the LCPQ with an instruction from LCP to LLD (S104). In the case of CMD_FRM_RCVD or CMD_FRM_SND, the offset value of the PPP packet is examined to determine the step S111. In the case of a compressed protocol through the process, the process proceeds to step S112 to post the IPC, and if not, the process proceeds to step S115 to investigate the PPP protocol.

In the case of PPP protocol search result PPP_LCP, Handshake_Auth, or Quality_Control in step S115, the process posts to LCPQ through step S118 (S119), and if it is PPP_IP, posts to IPQ (S114).

In addition, CMD_FRM_SND is used to transmit Ack, Nak, and Reject packets to LLD or to transmit IP packets to LLD during LCP and IPCP. While monitoring the Internet traffic, it negotiates a logical channel with the WNAS and transmits a frame (S105) to the corresponding channel (SendToPort).

After calling the data transmission routine (SendDataToNCCB) for transmission to the internal switch 15 (S106), a PPP frame (PPPFrame or MPFrame) is determined for transmission of data (S107), and then data transmission and reception for the basic channel is performed. (108 to S127) are performed.

At this time, the input data is separately managed a buffer to facilitate traffic monitoring. If the input frame is continuous beyond the threshold, a compressed protocol is performed after negotiation with the subscriber modem.

3 is a flowchart of a main task of adjusting bandwidth in a WSPB.

After various initializations, PPP packets input from the link layer drive task are examined, and BACP packets are sent to BACPQ, and BAP packets are sent to BAPQ. TCP / IP packets are sent to IPQ and sent over Ethernet.

The LLDQ is a packet in which all packets input and output from the subscriber are received. BACP process is classified by protocol number and shape information is obtained by code field. The BACP task handles negotiation between BACP peers when a BACP packet comes in from MLPPP packets from subscribers.

Once the BACP packet is sent from the link layer drive routine to BACPQ, the BACP packet entered into BACPQ is monitored by this queue in the BACPProcess task to receive input packets and negotiate BACP. In BACPProcess, the response packet processed by peer negotiation of BACP is transmitted to the subscriber. At this time, the packet is sent to the subscriber station through the channel task by sending the packet to the LLDQ.

The BAP protocol is used as a protocol for providing negotiation with a subscriber station for managing multiple PPP links of MLPPP. The BAPProcess is a task that a packet sent from a link layer drive task is delivered to a BAPQ, receives the forwarded packet from the BAPProcess, performs a negotiation procedure according to the packet, and sends a response packet to the LLDQ according to the current state to negotiate with the subscriber station.

After that, the packet is monitored according to the state transition diagram transmitted from the current PPP according to the BAP state transition diagram, and the bandwidth is automatically adjusted according to the data amount thereof.

While the invention has been shown and described in connection with specific embodiments thereof, it is well known in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the claims. Anyone who owns it can easily find out.

In the communication processing system according to the present invention operating as described above, if the bandwidth automatic adjustment method for Internet traffic change is provided, the channel is dynamically changed according to the available channel margin and the available bandwidth margin of the gateway through interworking with the public network. By allocating and bandwidth respectively, it is possible to improve the performance of the communication processing system. That is, by distributing the channel and the bandwidth according to the ratio of the allocated bandwidth to the traffic count, the transmission rate of the selected subscriber can be maintained at the maximum.

Claims (9)

The data communicated through the public data network (PNAS), the Internet (WNAS), the frame relay network (FNAS), etc., using the X.25 standard protocol, are interconnected to the public telecommunications network to the users of data communication connected to the public telephone network. In a gateway system for providing data communication service: An internal switch having a service processing board of various types of network matching modules, connected to each of existing networks connected in a standard TCP / IP manner, and responsible for relaying data traffic; A general telephone network access module having a telephone network matching board for negotiating trunk matching and subscriber modem and multiplexing data, and a telephone network service processing board for controlling an interface with the internal switch and processing a service; And A heterogeneous inter-gateway gateway system for improving communication speed, comprising: a system management device that manages the overall system operation and monitors changes in forwarded traffic in the system after establishing a channel connection to a communication subscriber to provide an optimal communication bandwidth. The method of claim 1, The telephone network matching board is processed in European PCM data format, operates with various subscriber modems and 56kbps, and supports trunks such as V.90 / V.34 / V.32bis and V.42 / V.42bis. Heterogeneous network gateway system for improving the communication speed, characterized in that it comprises an interface module. The method of claim 1, The telephone network service processing board receives the outgoing subscriber information through the telephone network matching board, allocates one channel among multiple subscriber modems, sets up a call path, and performs smooth information transmission through a flow control function of subscriber data. A communication user can simultaneously access the general telephone network access module at a speed of 56 kbps to retrieve database information connected to a packet network / frame relay network / internet and deliver the received information to a designated user at high speed. Heterogeneous network gateway system for improving the communication speed, characterized in that. The method of claim 1, The telephone network service processing board transmits network usage information and billing information to the system management device when the subscriber terminates the service in connection with the system management device, and periodically transmits the shape information and fault information of the currently operating system. Heterogeneous network gateway system for improving the communication speed, characterized in that for transmitting to. The method of claim 1, The telephone network service processing board is a heterogeneous inter-gateway gateway system for improving the communication speed, characterized in that for managing the resources required for communication and the transmission / reception task operating in a real-time operating system for the service support of multiple subscribers. In the resource allocation method in heterogeneous gateway system: A first step of allocating a plurality of assignable circuit resources according to the operation of the gateway system in each network; A second step of allocating circuit resources of the second network to circuits belonging to the first network to allow connection between the networks; A third step of monitoring a communication speed of a line belonging to the first network; And And a fourth step of increasing or decreasing the number of line resources of the second network allocated to the corresponding line if the communication speed of one of the lines belonging to the first network exceeds the threshold. . The method of claim 6, The second step is a resource allocation method in a heterogeneous gateway system, characterized in that to maintain a continuous control interval the total bandwidth of the flow between the Internet and the public communication network. The method of claim 6, The third step is a resource allocation method in a heterogeneous gateway system, characterized in that for determining the traffic count of the telephone network subscriber in the public telecommunication network. The method according to any one of claims 6 to 8, The fourth step is to adjust the bandwidth of the Internet according to the traffic count for the resources allocated in the first step, the bandwidth is at least one of the transmission path between the subscriber module and the service controller of the public communication network and the transmission path with the Internet Resource allocation method in a heterogeneous gateway system, characterized in that the allocation.