KR100236942B1 - Appatatus and method of processing atm cbr traffic in plug-in and play manner - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to an asynchronous transmission mode identity rate data processing apparatus and a method thereof.

2. The technical problem to be solved by the invention

The present invention utilizes a flexible and extensible plug-play scheme that can cope with user changes and adapt to different types of user data in an asynchronous delivery mode device that accommodates users using an asynchronous delivery mode adaptation layer 1 processor. An object of the present invention is to provide an asynchronous transmission mode identity rate data processing apparatus and method.

3. Summary of Solution to Invention

The present invention receives a data stream from a user and converts it into an asynchronous delivery mode cell and transmits it, receives an asynchronous delivery mode cell, converts it into a data stream and transmits it to a user, and a plurality of asynchronous delivery modes connected to each other by a token chain. Adaptive layer 1 processing means, cell bus means, and main processing means.

4. Important uses of the invention

The present invention is used in an asynchronous delivery mode system.

Description

Apparatus and method for asynchronous transfer mode identity rate data processing using plug-play method

The present invention relates to an asynchronous transfer mode (ATM) data processing apparatus and method, and more particularly, to an asynchronous transfer mode equality data processing apparatus and method using a plug-in and play (play-in) method.

In general, asynchronous transfer mode adaptation layer 1 processor (AAL 1) is an asynchronous transfer mode adaptation technique used for real-time communication of users who use voice or video. After configuring the asynchronous delivery mode cell payload by adding the octets related to the division and time information, attach the asynchronous delivery mode header to the asynchronous delivery mode cell payload to make the asynchronous delivery mode cell, and deliver it to the asynchronous delivery mode network. do. The asynchronous delivery mode cell received from the network passes through the reverse process and is delivered to the user as a data stream.

Looking at this in detail.

1 is a block diagram showing the configuration of an asynchronous transfer mode apparatus for receiving asynchronous transfer mode identity rate data to which the present invention is applied.

As shown in the figure, the main processor 101 is connected to the asynchronous delivery mode adaptation layer 1 processor 102 and the asynchronous delivery mode processor 103 to perform a control function, and the asynchronous delivery mode adaptation layer 1 processor 102 is Receives a data stream from the user to create an asynchronous delivery mode cell having time information at regular time intervals to the asynchronous delivery mode processor 103, the asynchronous delivery mode processor 103 delivers the input signal to the asynchronous delivery mode network do. Conversely, the asynchronous delivery mode processor 103 transfers the asynchronous delivery mode cell received from the asynchronous delivery mode network to the asynchronous delivery mode adaptation layer 1 processor 102, and the asynchronous delivery mode adaptation layer 1 processor 102 is inputted. The signal is converted into a data stream based on time information and transmitted to the user.

This conventional technology is not easy to add or delete the asynchronous delivery mode adaptive layer 1 processor function according to the increase or decrease of users using the asynchronous delivery mode adaptive layer 1 processor in the asynchronous delivery mode device, and simultaneously accommodates various different service classes. There is a problem that does not satisfy the requirements, the change of the user, the variety of service grade affects the performance of the system.

The present invention devised to solve the above problems can cope with the change of users in the asynchronous delivery mode device that accommodates users using the asynchronous delivery mode adaptation layer 1 processor, and can adapt to various types of user data. It is an object of the present invention to provide an apparatus and method for processing asynchronous transfer mode equality data using a flexible and scalable plug-play method.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing the configuration of an asynchronous delivery mode apparatus for accommodating asynchronous transfer mode identity rate data to which the present invention is applied.

Figure 2 is a block diagram showing the configuration of the plug-play asynchronous delivery mode identity ratio data processing apparatus according to an embodiment of the present invention.

3 is a block diagram illustrating an embodiment configuration of an asynchronous delivery mode adaptation layer 1 processor of the apparatus shown in FIG. 2;

4 is an initialization flow diagram of the asynchronous delivery mode adaptation layer 1 processor of the apparatus shown in FIG.

5 is a transmission flow diagram of the asynchronous delivery mode adaptation layer 1 processor of the apparatus shown in FIG.

FIG. 6 is a flow diagram of an asynchronous delivery mode adaptation layer 1 processor of the apparatus shown in FIG.

* Explanation of symbols for the main parts of the drawings

200-1 to 200-n: Asynchronous Transfer Mode Adaptive Layer 1 Processor

210: main processor 220: processor interface

230: cell bus 240: transmission bus

250: receive bus 260: clock bus

270: asynchronous delivery mode processor

300: communication control unit 310: division / reassembly unit

320: first-in, first-out 330: first-in, first-out

340: Individual Information Register 350: Cell Configuration

360: cell reception filter

In order to achieve the above object, the present invention receives data streams from each user, converts them into asynchronous delivery mode cells, and transmits them. A plurality of asynchronous delivery mode adaptive layer 1 processing means; Cell bus means coupled with said plurality of asynchronous delivery mode adaptive layer 1 processing means and carrying said asynchronous transport mode cell and providing a communication clock to said plurality of asynchronous delivery mode adaptive layer 1 processing means; And main processing means for controlling the plurality of asynchronous delivery mode adaptive layer 1 processing means.

In addition, the present invention, the asynchronous transmission mode adaptive layer 1 processor determines and records the identification value and the transmission rate, receives a communication clock from the outside, transfers the identification value and the transmission rate to the main processor, calculates and records the transmission frequency A first step of making; The asynchronous delivery mode adaptation layer 1 processor starts a transmission function, confirms receipt of the token chain signal, confirms the occurrence of the transmission frequency, obtains a transmission right, converts the data stream received from the user into an asynchronous delivery mode cell, and transmits the transmission. And transmitting a signal to the token chain; And the asynchronous delivery mode adaptation layer 1 processor starts a reception function, receives an asynchronous delivery mode cell, compares the virtual circuit identification value of the received asynchronous transmission mode cell header with the stored virtual circuit identification value, and matches or not. It is characterized in that it comprises a third step of converting the received asynchronous delivery mode cell into a data stream and transmitting to the user.

Hereinafter, an embodiment according to the present invention will be described in detail with reference to FIGS. 2 to 6.

2 is a block diagram showing the configuration of a plug-play asynchronous delivery mode equality data processing apparatus according to an embodiment of the present invention.

As shown in the figure, the asynchronous delivery mode adaptation layer 1 processors 200-1 to 200-n are connected to each other by a token chain, and are connected to the main processor 210 through a processor interface 220, and a cell bus. It is also connected to (230). The token chain is used to control the transmission right and is connected in a daisy chain form so that the asynchronous transmission mode adaptation layer 1 processors 200-1 to 200-n can connect and transmit when the transmission right is acquired. Enable the transmission of the asynchronous delivery mode adaptation layer 1 processor for a predetermined time by giving a priority, and the asynchronous delivery mode adaptation layer 1 processor 200-1 to 200-n does not acquire the transmission right. Is directly connected to the following asynchronous delivery mode adaptation layer 1 processors 200-1 to 200-n.

The asynchronous delivery mode adaptation layer 1 processors 200-1 to 200-n convert the data stream received from the user into an asynchronous delivery mode cell having time information and transmit the same to the transmission bus 240, and vice versa from the asynchronous delivery mode network. The received asynchronous transfer mode cells are received from the receive bus 250 and converted into a data stream according to time information and output to the user.

The main processor 210 is connected to the asynchronous delivery mode adaptation layer 1 processors 200-1 through 200-n through a processor interface 220 to perform a control function.

Cell bus 230 is a transmit bus 240 used for the asynchronous delivery mode cell transmission, a receive bus 250 used for receiving the asynchronous delivery mode cell, and a clock bus 260 used to provide a communication clock. And configured to be coupled to the asynchronous delivery mode adaptive layer 1 processors 200-1 to 200-n and the asynchronous delivery mode processor 270 to carry asynchronous delivery mode cells, and to carry out the asynchronous delivery mode adaptive layer 1 processor 200. -1 to 200-n) to transfer the communication clock.

FIG. 3 is a block diagram illustrating an embodiment configuration of an asynchronous delivery mode adaptation layer 1 processor of the apparatus shown in FIG. 2.

As shown in the figure, the communication control unit 300 is connected to the token chain, and is connected to the clock bus 260 of the cell bus 230 to receive a communication clock, and divided into the main processor 210 and the division. / Reassembly 310, and individual information register 340. The division / reassembly unit 310 is connected to the communication control unit 300 and is controlled by the communication control unit 300, receives a data stream from a user, or outputs a data stream to a user, and transmits a first-in first-out unit (FIFO). first in first out: 320 and a first-in, first-out 330. The first-in, first-out unit 320 is connected to the division / reassembly unit 310 and the cell component unit 350, and the first-in, first-out unit 330 is a cell receiving filter unit 360 and the division / It is connected to the reassembly 310. The cell configuration unit 350 is connected to the main processor 210 through the processor interface 220, and the first-in first-out unit 320, the cell reception filter unit 360, and the cell bus 230 are connected to the main processor 210. Is connected to the transmission bus 240, and the cell reception filter unit 360 is configured to receive the first-in first-out unit 330, the cell configuration unit 350, and the cell bus 230. 250). The individual information register 340 is connected to the main processor 210 through the communication control unit 300 and the processor interface 220.

Now, operation of the asynchronous delivery mode adaptation layer 1 processor according to the present invention will be described.

The communication control unit 300 combines the communication clock obtained from the clock bus 260 of the cell bus 230 with its transmission rate recognized from the individual information register 340 to obtain a cell frequency. After the calculation, the calculated cell frequency is stored. In addition, the communication control unit 300 receives a transmission command or a reception command from the main processor 210 through the processor interface 220 to drive the partition / reassembly unit 310, and a signal from the token chain is received. When it is received, it is determined whether a transmission frequency has occurred, and if a transmission frequency occurs, the transmission right is acquired to enable transmission for a predetermined time, and after transmission, the transmission time of one asynchronous transmission mode cell from the time of obtaining the transmission right. After a time delay, a signal is transmitted to the token chain to yield transmission rights to the next asynchronous transfer mode adaptation layer 1 processors 200-1 to 200-n, and if the transmission frequency does not occur, the next asynchronous transfer is performed. Delivery Mode Signals are sent to the token chain to yield transmission rights to the adaptive layer 1 processors 200-1 through 200-n.

The division / reassembly unit 310 is driven under the control of the communication control unit 300 and receives a data stream transmitted from a user, converts it into a 48 octet asynchronous delivery mode cell payload, and transmits the first-in first-out unit ( 320, and in turn, receives the 48 octets in the first-in, first-out unit 330, converts the data into a data stream, and delivers the data to users.

The first-in, first-out unit 320 stores the output of the division / reassembly unit 310 at the time of transmission, and the first-in, first-out unit 330 outputs from the cell reception filter unit 360 at the time of reception. Save it.

The cell configuration unit 350 asynchronously outputs the output of the first-in, first-out unit 320 while receiving and storing an asynchronous transmission mode virtual circuit identification value used as an asynchronous transmission mode header at the time of transmission and reception. It is configured as a delivery mode cell, and transmitted to the asynchronous delivery mode processor 270 through the transmission bus 240, the cell receiving filter 360 is a cell of the asynchronous delivery mode cell received from the receiving bus 250 The virtual circuit identification value in the header is compared with the asynchronous transmission mode virtual circuit identification value obtained from the cell configuration unit 350, and if it matches, the asynchronous transmission mode cell is received and stored in the first-in, first-out unit 330. .

The individual information register 340 stores the transmission rate and the identification value and provides the stored transmission rate to the communication controller 300, and the stored transmission rate and the identification value are provided to the main processor 210.

4 is an initialization flow diagram of the asynchronous delivery mode adaptation layer 1 processor of the apparatus shown in FIG.

As shown in the figure, when the asynchronous transfer mode identity factor data processing apparatus is driven, the asynchronous transfer mode adaptation layer 1 processors 200-1 to 200-n determine an identification value and a transmission rate, so that the individual information register ( After writing to 340 (400), the identification value and transmission rate information of the individual information register 340 is transmitted to the main processor 210 via the processor interface 220 (410), the cell bus 230 The communication control unit 300 calculates a cell transmission frequency for obtaining a transmission right by combining the communication clock and the transmission rate obtained through the communication unit 300, and stores the data in the communication control unit 300 (420) to complete the initialization.

5 is a transmission flowchart of an asynchronous delivery mode adaptation layer 1 processor of the apparatus shown in FIG.

As shown in the figure, the main processor 210 records the asynchronous transmission mode virtual circuit identification value in the cell configuration unit 350 through the processor interface 220 (500), and the communication control unit 300 Receiving a transmission command from the main processor 210 through the processor interface 220 (510) to start the transmission function (520) and at the same time to drive the transmission function of the partition / reassembly unit 310 ( 530). The division / reassembly unit 310 converts the data stream received from the user into a 48 octet asynchronous delivery mode cell payload when the transmission function is driven (531), and continuously converts the converted 48 octets into the transmission first-in first-out unit. After storing at 320 (532), it is determined whether to continue transmission (533), and if the transmission continues to be requested, the process returns to step 531; otherwise, the process returns to step 500.

On the other hand, the communication control unit 300 determines whether a signal is received from the token chain (521), and if a signal is received from the token chain, it is determined whether a transmission frequency has occurred. Otherwise, the next asynchronous transmission mode A signal is sent to the token chain (527) in order to yield transmission rights to the adaptation layer 1 processor. When receiving a signal from the token chain, the communication control unit 300 determines whether a transmission frequency has occurred (522), and if a transmission frequency has occurred, acquires a transmission right (523), otherwise, the following The asynchronous delivery mode signal is sent to the token chain (527) to yield transmission rights to the adaptation layer 1 processor.

When the transmission right is obtained from the token chain, the cell configuration unit 350 reads 48 octets from the first-in, first-out unit 320, and stores the asynchronous transmission mode virtual circuit identification value registered in the cell configuration unit 350. After creating an asynchronous transfer mode cell as a header (524), and transmits to the transmit bus 240 of the cell bus 230 (525). After the transmission right is used, after a time delay (526) by one asynchronous transmission mode cell transmission time from the time when the transmission right is acquired, the next asynchronous transmission mode adaptation layer 1 processor 200-1 to 200-n is sent. In order to concede the transmission right, a signal is transmitted to the token chain (527), and it is determined whether to continue transmission (528).

FIG. 6 is a flowchart illustrating an asynchronous delivery mode adaptation layer 1 processor of the apparatus illustrated in FIG. 2.

As shown in the figure, the main processor 210 records the asynchronous transmission mode virtual line identification value to the cell configuration unit 350 through the processor interface 220 (600), and the communication control unit 300 Receiving a receiving command from the main processor 210 through the processor interface 220 (610), starting the receiving function (620) and at the same time drives the receiving function of the partition / reassembly unit 310 (630). The asynchronous delivery mode cell received from the asynchronous delivery mode network receives the cell reception filter of the entire asynchronous delivery mode adaptive layer 1 processor 200-1 through 200-n through the receive bus 250 of the cell bus 230. It is transmitted to the unit 360 in the form of a broadcast (621), the cell reception filter unit 360 in the asynchronous transmission mode virtual circuit identification value of the cell configuration unit 350 and the virtual circuit of the cell header of the receiving asynchronous transmission mode cell Compare the identification values (622), determine whether they are the same (623), and if they are the same, store 48 octets of asynchronous delivery mode cell payloads in the receive first-in first-out 330 (624); If not, the cells are ignored.

After the asynchronous delivery mode adaptation layer 1 processors 200-1 to 200-n store 48 octets of the asynchronous delivery mode cell payload in the first-in first-out unit 330 (624), the main processor 210. 625 determines whether the reception is to be continued (step 625), and if it is requested to continue reception, returns to step 621; otherwise, returns to step 600.

Meanwhile, when the reception function is driven, the division / reassembly unit 310 reads (631) 48 octets in the reception first-in-first-out unit 330, converts the data into a data stream, and transfers the data stream to the user (631). The main processor 210 determines whether to continue the reception (632), and if it is requested to continue reception, returns to step 631; otherwise, returns to step 600.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains, and the above-described embodiments and accompanying It is not limited to the drawing.

The present invention as described above, in the asynchronous delivery mode environment, it is possible to flexibly provide real-time services by facilitating the additional deletion of the asynchronous delivery mode adaptation layer 1 processor function, which is a technology for providing real-time services such as voice, video, and various service classes There is an effect that can support a large number of users in real time.

Claims (14)

Receives data streams from each user and converts them into asynchronous delivery mode cells, and transmits them to asynchronous delivery mode cells, converts them into data streams, and sends them to users. AAL1) processing means; Signal transmitting means coupled with the plurality of asynchronous delivery mode adaptive layer 1 processing means and carrying the asynchronous transmission mode cell and providing a communication clock to the plurality of asynchronous delivery mode adaptive layer 1 processing means; And Main processor interface means for connecting the plurality of asynchronous delivery mode adaptive layer 1 processing means with an external main processor Asynchronous transmission mode identity rate data processing apparatus using a plug-play method comprising a. The method of claim 1, The token chain is It is used to control the transmission right. If the first asynchronous transmission mode adaptive layer 1 processing means is connected to transmit the transmission right when the first asynchronous transmission mode adaptive layer 1 processing means obtains the transmission right, Enable transmission of a first asynchronous delivery mode adaptive layer 1 processing means, and if the first asynchronous delivery mode adaptive layer 1 processing means is not acquiring a transmission right, subsequent second asynchronous delivery mode adaptive layer 1 processing An asynchronous transfer mode identity rate data processing apparatus using a plug-in method, characterized in that directly connected by means. The method of claim 2, The signal transmission means, A receive bus which carries the asynchronous delivery mode cells and provides them to the plurality of asynchronous delivery mode adaptive layer 1 processing means; A transmission bus for receiving and carrying said asynchronous delivery mode cells in said plurality of asynchronous delivery mode adaptive layer 1 processing means; And A clock bus for carrying said communication clock and providing it to said plurality of asynchronous delivery mode adaptive layer 1 processing means Asynchronous transmission mode identity rate data processing apparatus using a plug-play method comprising a. The method of claim 3, wherein Each asynchronous delivery mode adaptive layer 1 processing means, Communication control means connected to the token chain and receiving the communication clock from the clock bus to obtain the transmission right; And Receives a control signal from the communication control means and the main processor interface means, receives the data stream from a user, converts the data stream into the asynchronous transmission mode cell, transmits the data to the transmission bus, and receives the asynchronous transmission mode cell from the reception bus. Cell generation / separation means for converting into the data stream and transmitting to the user Asynchronous transmission mode identity rate data processing apparatus using a plug-play method comprising a. The method of claim 4, wherein The communication control means, Transmission rate obtaining means for obtaining the communication clock from the clock bus and obtaining its transmission rate from the cell generation / separation means; Cell frequency calculating means for calculating a cell frequency by combining the communication clock and the transmission rate; Transmission right acquiring means for acquiring the transmission right when the cell frequency occurs; And Control means for enabling transmission and reception by controlling the cell generation / separation means when the transmission right is obtained; Asynchronous transmission mode identity rate data processing apparatus using a plug-play method comprising a. The method of claim 5, The cell generation / separation means Split / Retransmitted by the control means to receive the data stream from the user, convert it into an asynchronous delivery mode cell payload, and to receive the asynchronous delivery mode cell payload, convert it into the data stream and send it to the user. Assembly means; First-in, first-out means for storing the asynchronous delivery mode cell payload, which is an output signal of the division / reassembly means; Receiving first-in, first-out means for storing and providing said asynchronous delivery mode cell payload in said dividing / reassembling means; Cell constituting means for storing an asynchronous delivery mode virtual circuit identification value and converting the output of said transmission first-in first-out means into an asynchronous delivery mode cell and delivering it to said transmission bus; Individual information register means for storing the transmission rate and the identification value to provide the transmission rate to the transmission rate obtaining means and to provide the transmission rate and the identification value to the main processing means; And Cell reception filter means for receiving the asynchronous transmission mode cell when the virtual circuit identification value of the cell header of the asynchronous delivery mode cell received from the reception bus is matched with the virtual circuit identification value; Asynchronous transmission mode identity rate data processing apparatus using a plug-play method comprising a. In the asynchronous transfer mode identity rate data processing method using a plug-play method, A first step of the asynchronous delivery mode adaptation layer 1 processor for determining and recording an identification value and a transmission rate, receiving a communication clock from an external source, transferring the identification value and the transmission rate to a main processor, and calculating and recording a transmission frequency; The asynchronous delivery mode adaptation layer 1 processor starts a transmission function, confirms receipt of the token chain signal, confirms the occurrence of the transmission frequency, obtains a transmission right, converts the data stream received from the user into an asynchronous delivery mode cell, and transmits the transmission. And transmitting a signal to the token chain; And The asynchronous delivery mode adaptation layer 1 processor starts a reception function, receives an asynchronous delivery mode cell, compares the virtual circuit identification value of the received asynchronous transmission mode cell header with the stored virtual circuit identification value, and determines whether there is a match. A third step of converting the received asynchronous delivery mode cell into a data stream and transmitting the same to the user Asynchronous transmission mode identity rate data processing method using a plug-in play made, including. The method of claim 7, wherein The first step is A fourth step of recording the identification value and the transmission rate in a separate information register; Transmitting the identification value and the transmission rate to the main processor through a processor interface; And A sixth step of the communication control unit calculating and recording the transmission frequency from the communication clock and the transmission rate input from the outside; Asynchronous transmission mode identity rate data processing method using a plug-in play made, including. The method of claim 8, The second stage A seventh step of recording the asynchronous transmission mode virtual circuit identification value into a cell configuration unit and the communication control unit receiving the transmission command; An eighth step of, when the communication control unit starts a transmission function and the token chain signal is transmitted, acquiring the transmission right, converting the data stream input from the user into the asynchronous transmission mode cell, and transmitting the converted data stream; And A ninth step of transmitting a signal to the token chain after a time delay corresponding to a transmission time of the asynchronous transfer mode cell after using the transmission right; Asynchronous transmission mode identity rate data processing method using a plug-in play made, including. The method of claim 9, The eighth step, A tenth step of converting and storing the data stream received from the user into an asynchronous delivery mode cell payload when the transmission function is started; And An eleventh step of acquiring the transmission right when the transmission function is started, acquiring the transmission right, and converting the asynchronous delivery mode cell payload into the asynchronous delivery mode cell and transmitting the same; Asynchronous transmission mode identity rate data processing method using a plug-in play made, including. The method of claim 10, The eleventh step, A twelfth step of receiving the token signal from the token chain; A thirteenth step of checking whether the transmission frequency has occurred; A fourteenth step of acquiring the transmission right according to the confirmation result; And A fifteenth step of reading the cell payload and creating the asynchronous delivery mode cell and transmitting it; Asynchronous transmission mode identity rate data processing method using a plug-in play made, including. The method according to any one of claims 7 to 11, The third step, A sixteenth step of recording the asynchronous transmission mode virtual circuit identification value and receiving a reception command; And Starting the receiving function and comparing the asynchronous delivery mode header with the virtual circuit identifier to receive the asynchronous delivery mode cell delivered from a cell bus, converting the data stream to a user, and transmitting the same; Asynchronous transmission mode identity rate data processing method using a plug-in play made, including. The method of claim 12, The seventeenth step, An eighteenth step of reading the stored asynchronous transmission mode cell payload and converting the stored data into the data stream when the reception function starts; And A nineteenth step of comparing the asynchronous transmission mode cell header received from the cell bus with the virtual circuit identification value and converting the asynchronous transmission mode cell into an asynchronous transmission mode cell payload when the reception function is started; Asynchronous transmission mode identity rate data processing method using a plug-in play made, including. The method of claim 13, The nineteenth step, A twentieth step of receiving the asynchronous delivery mode cell; A twenty-first step of confirming whether the received asynchronous delivery mode cell header and the asynchronous delivery mode virtual circuit identification value are the same; And A twenty-second step of converting and storing the asynchronous delivery mode cell into the asynchronous delivery mode cell payload according to the confirmation result; Asynchronous transmission mode identity rate data processing method using a plug-in play made, including.

Images