KR100232878B1 - Dynamic bandwidth utilizing method for network service of asynchronous transfor mode - Google Patents

Abstract

The present invention relates to a method for dynamically utilizing bandwidth in an asynchronous mode system that provides a connection priority service and a connectionless priority service. The first process of allocating a first bandwidth when a call setup signal of the connection priority service is input; A second process of performing a call setup process after setting the first bandwidth to a temporarily usable bandwidth after performing the first process, and a call setup signal of a connectionless priority service after performing the second process is inputted A third process of determining whether a temporary bandwidth is available after allocating a second bandwidth, and if the temporary bandwidth is present as a result of the determination of the third process, converts the second bandwidth and the temporary bandwidth to a final bandwidth. A fourth process of allocating and transmitting data of a connectionless priority service, and a fifth process of releasing the second bandwidth after performing the fourth process It is characterized by.

Description

DYNAMIC BANDWIDTH UTILIZING METHOD FOR NETWORK SERVICE OF ASYNCHRONOUS TRANSFOR MODE}

The present invention relates to a method of utilizing bandwidth in a network service of an asynchronous transfer mode (hereinafter referred to as "ATM") network, and in particular, a connectionless oriented bandwidth allocated from a connection oriented service. It relates to the dynamic bandwidth utilization method used in the service.

The network service of ATM network has connection priority service and connectionless priority service.

1 is a view schematically showing an asynchronous mode network.

Referring to the drawings, reference numeral 10 denotes a subscriber station device, and 20 denotes an ATM switch forming a network. Here, the connection priority service is fixed to the bandwidth allocated between the subscriber station 10 and the ATM switch 20 to transmit subscriber data such as voice or video. On the other hand, in the connectionless priority service, subscriber data is transmitted using the maximum bandwidth possessed by the subscriber station 10. In this case, the subscriber data of the non-connection priority service is non-continuous data that is input aperiodically.

2 is a block diagram of the asynchronous mode switch of FIG.

Referring to the drawings, reference numeral 21 in the drawings is a controller, which controls the overall operation of the ATM switch. 22 is a memory that temporarily stores an execution program of an ATM switch and data generated when executing the program. Reference numeral 23 denotes a subscriber connection unit which, under the control of the control unit 21, performs interface processing between the transmission path and the ATM switching period. Although not shown, the subscriber access unit 23 includes a usage parameter control unit, a maintenance operation management unit, and a header conversion unit. The usage parameter control unit monitors the flow rate of the cell. The maintenance operation manager detects whether the transmission line or the exchange is operating normally or monitors the performance of cell loss or operation error. The header conversion unit converts the virtual channel identifier used on the transmission path into a virtual channel identifier to be used in the self-routing switch unit and the output transmission path. 24 is a self-routing switch unit, which is controlled by the control unit 21 and is output based on the header information of the cell. 25 denotes a network connection unit, which is controlled by the controller 21, outputs a cell output from the self-routing switch unit 24 to the output transmission path, and checks whether the output transmission path is normally operating.

3 is a flowchart illustrating a call establishment and release process of a connection priority service in a network service of an asynchronous mode network.

Hereinafter will be described in detail based on the configuration of FIG.

First, a call setup signal for requesting call setup from the calling party subscriber terminal device to the network is outputted to the ATM switch 20 of the network. The call setup signal includes a telephone number of a receiving subscriber station and information such as a desired service grade and a cell rate. The ATM exchanger 20 then outputs a call progress signal to the calling subscriber station indicating that the call is attempting to be connected to the receiving subscriber station according to the call establishment signal. Thereafter, the call setup signal is output to the receiving subscriber station. Then, the receiving subscriber station terminal outputs a call setup reception signal informing the caller that the call setup signal has been received, and the network receives the call setup reception signal and outputs the call setup reception signal to the calling subscriber terminal device. Here, the call setup reception signal is a ring signal. Then, when the receiver hears the ring signal and responds, the receiving subscriber station outputs a connection response signal indicating that the receiver responds to the call setup signal to the network. Then, the network receives the connection response signal to the receiving subscriber station and outputs the connection response signal to the calling subscriber station. Then, the calling subscriber terminal device receives this and outputs a connection response confirmation signal to the network. When the call setup is made in this way, the calling subscriber station and the receiving subscriber station transmit data using the network. When the data transmission ends and the release subscriber station device outputs a release signal for releasing a call setting from the network, the network sends a release completion signal to the caller terminal device and outputs a release signal to the receiving subscriber station device. The receiving subscriber station receives the release signal and sends a release completion signal to the network in response thereto.

4 is a flowchart illustrating a conventional bandwidth utilization process in a network service of an asynchronous mode network.

It demonstrates in detail based on the structure of FIG. 2 mentioned above.

As used herein, the connected call setup signal refers to a call setup signal used in the case of a connection priority service, and the connectionless call setup signal refers to a call setup signal used in the case of a connectionless priority service.

The originating subscriber station generates a connected call setup signal or a disconnected call setup signal and outputs it to the ATM switch. Then, it is received by the subscriber access unit 23 of the exchange and output to the control unit 21. Then, in step 100, the control unit 21 of the exchange determines whether the input signal is a connected call setup signal. If it is determined in step 100 that the call setup signal is connected, in step 110, the controller 21 allocates a first bandwidth. Then, in step 120, the control unit 21 outputs a call progress signal to the calling subscriber terminal device, and performs a call setup process by outputting the connected call setup signal to the output transmission path through the network connection unit 25. Then, when the access response signal output in response to the response from the receiving subscriber station terminal in step 130 is input to the control unit 21 through the network connection unit 25 in step 140 transmits the data using the allocated first bandwidth do. After that, when the data transmission ends in step 150 and a release signal is input through the subscriber access unit 23, the controller 21 releases the first bandwidth allocated in step 160. In operation 170, if the determination result of the operation 100 is not the connection-type call setup signal but the connection-type call setup signal, in step 180, the controller 21 allocates the second bandwidth. After that, in step 190, the controller 21 transmits data using the second bandwidth. When the transmission of data is completed, the second bandwidth is released in step 200.

As described above, it takes some time (seconds) to complete the connected call setup process. However, in the conventional network service, when the connection call setup signal is input, the allocated bandwidth cannot be utilized while the connection call setup process is performed.

Accordingly, an object of the present invention is to provide a dynamic bandwidth utilization method that uses the allocated bandwidth as the bandwidth of a connectionless priority service until the call setup process is completed in the connection priority service.

In order to achieve the above object, the present invention provides a method for dynamically utilizing bandwidth in an asynchronous mode system providing a connection priority service and a connectionless priority service, wherein a first bandwidth is allocated when a call setup signal of the connection priority service is input. A second process of setting a first bandwidth to a temporarily usable bandwidth after performing the first process, performing a call setup process, and a non-connected priority service after performing the second process A third process of determining whether a temporary bandwidth is available after allocating a second bandwidth when a call setup signal of A is input; and if the temporary bandwidth is present as a result of the determination of the third process, the second bandwidth and the temporary usage A fourth process of transmitting data of an unconnected priority service by allocating a usable bandwidth as a transmission available bandwidth; Characterized in that the fifth process to release.

1 is a view schematically showing an asynchronous mode network.

2 is a block diagram of the asynchronous mode switch of FIG.

3 is a flowchart illustrating a call establishment and release process of a connection priority service in a network service of an asynchronous mode network.

4 is a flowchart illustrating a conventional bandwidth utilization process in a network service of an asynchronous mode network.

5 is a flowchart illustrating a process of utilizing dynamic bandwidth in a network service of an asynchronous mode network according to an embodiment of the present invention.

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

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

5 is a flowchart illustrating a bandwidth utilization process in a network service of an asynchronous mode network according to an embodiment of the present invention.

Hereinafter, a detailed description will be made based on the configuration of FIGS. 1 and 2 described above.

The originating subscriber station generates a connected call setup signal or a disconnected call setup signal and outputs it to the ATM switch. Then, it is received by the subscriber access unit 23 of the exchange and output to the control unit 21. Then, in step 300, the control unit 21 of the exchange determines whether the input signal is a connected call setup signal. If it is determined in step 300 that the connected call setup signal is received, the controller 21 allocates a first bandwidth in step 310. Thereafter, in step 320, the controller 21 uses the maintenance operation manager of the subscriber access unit 23 as the memory 22 as the bandwidth temporarily available in the connectionless priority service until the call setup process is completed. Store in Then, in step 330, the controller 21 performs a call setup process. If the connectionless call setup signal is input to the controller 21 while the call setup process is performed in operation 340, the controller 21 allocates the second bandwidth in operation 350. Then, in step 360, the controller 21 accesses the memory 22 to determine whether there is a temporary available bandwidth. If there is a temporary available bandwidth as a result of the determination, in step 370, the controller 21 transmits data using the second bandwidth and the temporary available bandwidth as the available bandwidth. Then, when data transmission is completed, the controller 21 releases the second bandwidth in step 380.

If there is no temporary bandwidth available as a result of the determination of operation 360, in operation 390, the controller 21 transmits data using only the second bandwidth and then performs operation 380. If the signal input in step 340 is not a connectionless call setup signal and is a connection response signal, in step 400, the controller 21 receives the connection response signal and outputs a connection response confirmation signal to a receiving subscriber station device. The terminal apparatus outputs a connection response signal. Thus, in step 410, the controller 21 releases the temporarily usable bandwidth and transmits the input data using the first bandwidth. Thereafter, if a release signal is input after data transmission is completed, the controller 21 receives the release signal and releases the first bandwidth in step 430.

As described above, the present invention temporarily reduces the waste of bandwidth and increases data transmission efficiency by temporarily using the allocated bandwidth from the connectionless priority service until the call establishment process of the connection priority service is completed. We try to improve. As a result, the present invention can minimize the cost of subscribers due to bandwidth usage.

Claims (3)

In a method for dynamically utilizing bandwidth in an asynchronous mode system providing connection priority service and connectionless priority service, A first process of allocating a first bandwidth when a call establishment signal of a connection priority service is input; A second process of performing a call setup process after setting the first bandwidth to a temporarily available bandwidth after performing the first process; A third process of determining whether a temporary bandwidth is available after allocating a second bandwidth when the call setup signal of the unconnected priority service is input after performing the second process; A fourth process of transmitting data of a connectionless priority service by allocating the second bandwidth and the temporary usable bandwidth as a transmission available bandwidth if a temporary available bandwidth exists as a result of the determination of the third process; And a fifth process of releasing the second bandwidth after performing the fourth process. The method of claim 1, further comprising: a sixth step of releasing the second bandwidth after transmitting data using only the second bandwidth if the temporary available bandwidth does not exist as a result of the determination of the third step. Way. The method of claim 1, After performing the second process, if the call setup signal of the unconnected priority service is not input and the connection response signal is input, the temporary available bandwidth is released, and data is transmitted using the first bandwidth. And a seventh process of releasing one bandwidth.

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