KR100297859B1 - Method for supporting guaranteed frame rate in atm - Google Patents

Abstract

The present invention relates to a subscriber matching device in an asynchronous transmission mode, and more particularly, to a subscriber matching device for providing a guarantee frame rate service. The present invention is a subscriber matching device including a cell conversion unit, a switching interface unit and a physical layer interface unit in the asynchronous transmission mode subscriber matching apparatus, when the guarantee frame rate service cell input from the physical layer, the predetermined control under the guarantee A corresponding frame rate table that stores information on a frame rate service, and a corresponding frame information is read and output from a data cell and a guarantee frame rate table under predetermined control when the guarantee frame rate service cell is input. A receiver, receiving the guarantee frame rate cell and corresponding information, and determining whether to transmit the guarantee frame rate service cell based on the information, and if the determination result is transmission, guarantees until the effective load type identifier of the header is a predetermined value. Receive a frame rate service cell and change the cell And a protection-type frame rate controller outputting part, characterized by made of an control unit for controlling the receiver.

Description

Subscriber matching device providing guarantee frame rate service in asynchronous transmission mode {METHOD FOR SUPPORTING GUARANTEED FRAME RATE IN ATM}

The present invention relates to a subscriber matching device in an asynchronous transmission mode, and more particularly, to a subscriber matching device for providing a guarantee frame rate service.

In general, the subscriber matching device in the asynchronous transmission mode substantially supports only a constant bit rate (CBR) service and a variable bit rate service (VBR). This will be described in detail with reference to FIGS. 1 and 2.

1 is a block diagram illustrating a general subscriber matching device, and FIG. 2 is a diagram illustrating a virtual path identification table and a connection identification table used in a general asynchronous transmission mode.

The controller 101 controls the overall operation of the subscriber matching device. The receiver 103 has a virtual path identification table, a connection identification table, and a buffer as shown in FIG. When the cell is received from the physical layer, the receiving unit 123 detects and analyzes the VPI and VCI of the cell from the header, and then reads connection information previously registered with the VPI from the connection identification information table of FIG. Together with the cell converter 107, the output is performed. The user parameter control unit 105 monitors the receiving unit 103. That is, the user parameter control unit 105 monitors whether the inputted cells exceed the cell flow rate preset for the subscriber transmitting the cell. If the inputted cells exceed the preset cell flow rate, the user parameter controller 105 discards the excess portion and the existing cells. It is possible to increase the efficiency of resources by monitoring the flow rate of the inputted cells for all services except the guaranteed frame service and delivering the cells in units of frames for the remaining resources. Under the control of the control unit 101, the cell converting unit 107 imposes routing information on the cell input from the receiving unit 103 and converts it into a virtual channel identifier to be used in the switching link matching unit 109 and the output transmission path. It outputs to the said switching link matching part 109 or an output transmission path (not shown). In addition, the cell converter 107 transmits the routing information to the cell input from the switching link matching unit 109 to the transmitter 113. The transmitter 113 receives the cell and transmits the cells to the physical layer by the reverse process of the receiver 123. The distributor 115 monitors the transmitter 113 and distributes the input cells to the physical layer so as not to exceed the cell flow rate when the cells processed in the transmitter 113 exceed the cell flow rate. The clock receiving distributor 111 receives the system clock, and receives the user variable controller 105, the receiver 103, the transmitter 113, the distributor 115, the switching link matching unit 109, and the cell converter 107. The clock is divided and provided.

In FIG. 2, it is shown that a connection identifier (Conn-Id) is taken from the input cell with VPI and VCI to manage a table, and various parameters according to connection and ATM services are defined.

As described above, the subscriber matching apparatus having the above configuration actually supports only the fixed bit rate service and the variable bit rate service, so that appropriate use of the remaining band is required. In addition, existing services (fixed bit rate services and variable bit rate services) exhibit limitations in transmitting and receiving data and voice information that are currently emerging. And in terms of resource utilization, its utilization is increasing. To overcome these limitations and meet user needs, it is necessary to accommodate Available Bit Rate (ABR), Unrestricted Bit Rate (UBR) and Guaranteed Frame Rate (GFR) services. This is emerging.

However, the conventional subscriber matching device causes many problems in various services, processing thereof, and thus traffic management, and causes a lot of loss in bandwidth use in real time.

Accordingly, an object of the present invention is to provide a subscriber matching device capable of providing a guarantee frame rate service using a payload type identifier (PTI) in an asynchronous transmission mode.

In order to achieve the above object, the present invention provides a subscriber station matching device including a cell converting unit, a switching interface unit, and a physical layer interface unit. The corresponding information about the input cell is read from a data cell and a guarantee frame rate table under predetermined control when the guarantee frame rate table stores information about the guarantee frame rate service and the guarantee frame rate service cell. A receiving unit for outputting, the guarantee frame rate cell and corresponding information, and determining whether to transmit the guarantee frame rate service cell based on the information. Receives a guaranteed frame rate service cell until the cell And a protection-type frame rate control unit for output to the affected part, characterized by made of an control unit for controlling the receiver.

1 is a block diagram of a general subscriber matching device.

2 is a view showing a virtual path identification table and a connection identification table used in a general asynchronous transmission mode.

3 is a diagram illustrating a subscriber matching device in an asynchronous transmission mode according to an embodiment of the present invention.

4 is a diagram illustrating a disassembly and assembly service data unit of an asynchronous transmission mode according to an embodiment of the present invention.

3 is a diagram illustrating a subscriber matching device in an asynchronous transmission mode according to an embodiment of the present invention.

3, the controller 137 controls the overall operation of the subscriber matching device according to the present invention. The control unit 137 performs interprocessor communication (IPC communication) and maintenance, administration and management (OAM) processing. The controller 137 used the MPC 860 to perform the above functions. The receiver 123 receives a cell through the physical layer interface unit 121 and detects and analyzes a VPI and a VCI included in a header of the cell under the control of the controller 137. Since the controller 137 knows in advance about the type of the cell to be input, if the cell corresponds to a fixed bit rate service and a variable bit rate service, the controller 137 controls the receiver 123 to process the cell as shown in FIG. 139). In this case, the user variable controller 125 monitors the receiver 123 and determines whether the inputted cell flow rate exceeds a preset cell flow rate. However, if the inputted cell is a guarantee frame rate service cell, the controller 137 controls the receiver 123 to check the guarantee frame rate table 127 to determine information corresponding to the corresponding VPI and VCI [Maximum Frame Size MFC), etc.] are read out and output to the guarantee frame service control unit 129. The guaranteed frame rate service controller 127 receives the data read from the data cell and the guaranteed frame rate table 127 and determines whether the cells are input within a preset maximum frame size. As a result, if the inputted cells exceed the preset maximum frame size, the guaranteed frame rate service controller 129 discards all cells and does not transmit them. However, if the inputted cells do not exceed the preset maximum frame size, the guaranteed frame rate service control unit 129 continues to operate the cell until the AUU value of the effective load type identifier (PTI) included in the head of the cell becomes 1. Receive input. The guarantee frame rate service control unit 129 operates by the F-GCRA algorithm in I.371. The MFS must be determined at call setup. Otherwise, it is difficult to determine the buffer size and queue size. The input cell is output to the cell converter 139, and the inputted cell converter 139 adds routing information to a header and outputs it through the switching interface 141. The transmitter 131 receives a fixed bit rate service and a variable bit rate service cell from the cell output from the switching interface unit 141 through a cell converter 139, and guarantees a frame service cell from the guarantee frame rate table 129. Receive the input. If the inputted cell is a guarantee frame rate cell, the transmitter 131 transmits to the physical layer interface 121, and if the guarantee frame rate service cell, the transmitter 131 transmits the guarantee frame rate service cell to the guarantee frame rate table 135. The AUU of the PTI is set to 0 and only the last AUU is set to 1 by the MFC set by the MFC to be transmitted to the physical layer interface unit 121. The distribution unit 133 determines whether the cells transmitted from the transmitter 131 to the physical layer exceed the set cell flow rate when the cells output from the cell converter 139 are fixed bit rate service and variable bit rate service cells. As a result of determination, when the inputted cells exceed the preset cell flow rate, the excess cells are distributed and output.

4 is a diagram illustrating a disassembly and assembly service data unit of an asynchronous transmission mode according to an exemplary embodiment of the present invention, illustrating a process in which the guarantee frame rate control unit 129 is processed by the F-GCRA algorithm in I.371. will be. The guarantee frame rate controller 129 checks and processes the AUU parameter of the PT, and registers the parameter in the guarantee frame rate variable controller 127. And since the contour must be known at the ATM layer, the controller 137 of the subscriber matching device updates the parameters used in the guaranteed frame rate service, and shares or exchanges the connection information with the upper block TMN.

Asynchronous transmission mode subscriber matching device has an advantage that can support the existing data transmission, such as guarantee frame rate service to support guarantee frame rate service.

Another advantage of the present invention is that by supporting the guarantee frame rate service has the advantage that it can have a wide range of applications from Internet service and data delivery to non real-time applications.

Another advantage of the present invention is that by using a fixed bit rate and a variable bit rate service and utilizing the remaining bandwidth, the asynchronous transfer mode switch can be fully utilized. That is, by accommodating the guarantee frame rate service in the asynchronous transmission mode subscriber matching device, there is an advantage that the maximum bandwidth that the board can digest. Therefore, the effective non-real-time data service can be created by dividing the size of data in units of frames, so the service of delivering wireless data messages in units of frames rather than real time has the advantage of being possible.

Claims (4)

In the asynchronous transmission mode subscriber matching device including a cell conversion unit, a switching interface unit and a physical layer interface unit, A guarantee frame rate table storing information on the guarantee frame rate service under predetermined control when a guarantee frame rate service cell is input from a physical layer; A receiver which reads and outputs corresponding information on the input cell from a data cell and a guarantee frame rate table under predetermined control when the guarantee frame rate service cell is input; Receiving the guarantee frame rate cell and the corresponding information, and determining whether to transmit the guarantee frame rate service cell according to the information; if the determination result is transmission, guarantee frame rate service until the effective load type identifier of the header is a predetermined value. A guarantee frame rate controller for receiving a cell and outputting the cell to the cell converter; Subscriber matching device for providing a guarantee frame rate service, characterized in that the control unit for controlling the receiving unit. 2. The subscriber matching device of claim 1, wherein the information is maximum frame size information. The guarantee frame rate service of claim 2, wherein the determination of whether to transmit the guarantee frame rate service cell is determined by whether the guarantee- input frame guarantee service cells are within the maximum frame size. Subscriber registration device. 2. The subscriber matching device of claim 1, wherein a guaranteed frame rate service cell is input until a value of the effective load state identifier is one.