KR100496638B1 - Inverse multiplexing apparatus for switching system with QoS and CoS - Google Patents

Abstract

The present invention relates to an apparatus and method for demultiplexing an exchange system that supports QoS and CoS. Data distribution; A transmission data transmission unit having a plurality of detailed paths for transmitting transmission data distributed by a frame distribution unit; and a transmission data assembly unit reassembling the frames according to an order relationship of transmission data transmitted from the transmission data transmission unit, Since the implementation complexity of the area, the delay time, etc. is small and the circuit is simple to implement, it can be effectively used for the implementation of a large-capacity demultiplexing system such as an IP packet, an ATM cell, and a frame.

Description

Inverse multiplexing apparatus for switching system with QoS and CoS}

The present invention relates to a large-capacity exchange system, and more particularly, to a demultiplexing apparatus and method for providing the same service as using a single large-capacity communication path by distributing and sequentially collecting digital transmission data using a plurality of low-speed low-capacity paths. It is about.

The demultiplexing means can be divided into two processes: distributing a given transmission data into multiple detailed paths, and reassembling the transmitted transmission data in order, and inexpensive transmission and switching system as the bandwidth of the transmission link or switching system increases. There is an advantage that can be used to make a more broadband system. The demultiplexing means has the advantage of being economical because it consists of low-cost, small-capacity switches using detailed paths, but it properly load-transmits the transmission data into multiple detailed paths and re-delivers the transmitted transmission data in order. Support for disassembly, reassembly, and recovery of data sequence in case of failure.

Currently, demultiplexing means are used in various applications such as ATM AAL layer and switching system, and conventional demultiplexing techniques include BONDING (Bandwidth on deamnd), MP (Multilink Point-to-Point protocol), parallel ATM switch, Packet Examples include striping, CCITT H.221 (A Channel Aggregation method for video conferencing), IMA (Inverse Multiplexing for ATM), SCIMA (Switched Connection Inverse Multiplexing for ATM), AFR (Advanced Frame Recovery). Demultiplexing in the ATM AAL layer divides the ATM cell stream received from the ATM layer into cell units and transmits them through multiple links in order to increase the transfer capacity, and then the receiver combines the cells transmitted through each link. It uses the process of restoring the original ATM cell stream and sending it to the ATM layer. The demultiplexed switching system using multiple switching planes has been mainly studied to overcome the performance degradation caused by the HOL blocking phenomenon. In recent years, a plurality of switching planes have been used to increase the transfer capacity of the switching system. The demultiplexing researches used are actively being conducted.

IMA is a synchronous demultiplexing means adopted as a standard in May 1997 for ATM systems that round-points a point-to-point data stream over multiple physical links. robin) means of delivery. Demultiplexing delivers a given data to many different detail paths, resulting in cell delay variations (CDVs), which have different propagation times for each detail path. The IMA adjusts the link delay time by inserting a separate ICP (IMA Control Protocol) into each IMA frame with information for reconfiguring the cell order and detecting the arrival time at each receiver. When the transmitter continuously transmits cells, if there are no cells between the ICP cells in the IMA frame, filler cells are inserted to maintain a continuous cell stream in the physical layer and maintain the speed between cell layers. IMA has a disadvantage in that bandwidth is wasted due to ICP cells and filler cells added to adjust the cell order, and recovery is not possible in case of unpredictable massive cell delay variation between each detailed path link.

Switched Connection Inverse Multiplexing for ATM (SCIMA) is an improved asynchronous demultiplexing means introduced in 1998. SCIMA recovers the order of cells for each virtual path (VC), and builds a linked list using the sequence value of each subpath and the detailed path number of the next cell to be transmitted instead of the sequence number between cells. By predicting the detailed path number of the cell to be delivered next time, it is possible to recover the order in constant time even when using many detailed paths, and even if a large cell delay time transition between unexpected virtual paths occurs, Restore the order. SCIMA has much less execution time and area than the IMA, and does not insert additional cells, thus reducing bandwidth waste and recovering cell order in the event of a single cell loss. There is an advantage. If more than one consecutive cell loss occurs, SCIMA cannot recover the order of the cells.In this case, ACI (Advanced Frame Recovery) reverses the cells in the frame where the cell loss occurred and initiates the cell recovery process from the next frame. A multiplexing device has been proposed.

The existing demultiplexing algorithm assumes that the transmission order of cells / packets / frames delivered on each transmission path is maintained, but the demultiplexing switching system that supports QOS (Quality of Service) and COS (Class of Service) is supported. In this case, the order of the data delivered in the detailed path is changed according to the class and priority of the transmission data, and it is difficult to apply it directly to a large-capacity demultiplexing switching system because the order must be maintained for each traffic type and class. There is a disadvantage that the area is required.

The technical problem to be achieved by the present invention, to solve the above problems by using a switch that supports Quality of Service (QoS), Class of Service (CoS) as a detailed transmission path to support QoS and CoS to improve the implementation complexity An apparatus and method for demultiplexing an exchange system are provided.

Another object of the present invention is to provide a computer-readable recording medium having recorded thereon a program for executing the method on a computer.

De-multiplexing apparatus of the switching system supporting QoS and CoS according to the present invention, the transmission data distribution unit for receiving the transmission data to classify by the flow of the transmission data having a sequence relationship of transmission and to transmit to the next stage; A transmission data transmission unit having a plurality of detailed paths for transmitting the transmission data distributed by the distribution unit; A transmission data assembly unit for reassembling the frames in order of the transmission data transmitted from the transmission data transmission unit.

In the demultiplexing method of an exchange system supporting QoS and CoS according to the present invention, (a) receiving data frames and classifying them for transmission to a later stage; (b) determining the order of the classified data frames (c) transmitting the data frames having the order in a predetermined number of detailed paths; (d) arranging the data frames transmitted in the detailed paths according to the order of the step (b). .

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

The most problematic part of implementing a demultiplexed switching system is to reduce the number of streams of data that must be kept in order. The demultiplexing system rearranges the number of flows, and the unit of flow can be variously designed. In the case of ATM cell traffic using a destination address, there is a 256K virtual channels (Virtual Channel, VC) by flow and, IPv4 traffic is 2 ^32, IPv6 traffic 32bit address uses a 128bit addresses and 24bit flow label ²¹⁵² Can have the maximum flow of. Currently, commercial routers cannot handle all the large address spaces, so only 30K ~ 50K addresses are managed using a lookup table. Can be.

The conventional SCIMA demultiplexing switching means not only has a disadvantage in that it can be directly implemented by managing data flow for each virtual channel , but also has a feature of transmitting virtual channel flows in multiple detail paths in order if the transmission order is to be maintained. There is a constraint that the delivery capacity of the virtual channel flow cannot exceed the delivery capacity of each detailed delivery path.

Recently, switching system considers QOS (Quality of Service), COS (Class of Service), etc., so that the delivery order is changed by one transmission path or priority of transmission data in switching path. The order must be maintained separately according to traffic types and traffic classes such as point to point, multicasting, and broadcasting. Existing demultiplexing means, which assume that the order of data delivered through one detailed transmission path does not change, are difficult to apply to switching systems supporting QOS and COS. For a demultiplexed switching system that uses k switches as a detailed forwarding route to distribute and aggregate traffic, O (number of flows * k) queues are required for the reassembly , for example, four types (point-to-point, Point-to-many, etc.), 16 * 16 switching system that handles 8 QoS class transmission data has 16 * 16 * 8 * 4 = 8K flows, and reassembly when passing through 4 switches At least 16 * 16 * 8 * 4 * 4 = 32 K or more queues are required.

Due to the above reasons, the number of transmission data flows, which is a unit to be rearranged when manufacturing a large-capacity demultiplexing switching system, is difficult to implement. Since 300 queues can be implemented in 3 million gate FPGAs, the problem of appropriately reducing the flow, which is a realignment unit, has emerged as a decisive problem in implementing a large-capacity demultiplexing switching system. Means for reducing the number of traffic flows are essential for demultiplexed switching systems.

1 is a diagram illustrating a basic structure of a demultiplexing switching system for distributing and transmitting transmission data such as a cell, a packet, or a frame into a plurality of transmission paths.

The transmission data 111 receives the cells, packets or frames that are the transmission data 111 and distributes the transmission data 111 to be transmitted from the transmission data distribution unit 110 to the detailed path 130, and the transmission data reassembly unit 120 transmits the detailed path ( 130 to reassemble the data transmitted through the output to the output transmission data (122).

2 is a diagram illustrating a structure of a demultiplexed switching system supporting QoS or CoS according to the present invention, and is a device for dividing a virtual path of traffic into a plurality of detailed paths using a plurality of detailed paths having a smaller capacity. .

The transmission data distribution unit 210 distributes a cell, a packet, or a frame, which is an input transmission data 211, and the transmission data transmission unit 230 transmits transmission data distributed in each detailed path. The transmission data assembly unit 220 reassembles and outputs the data transmitted through the detailed path into the output transmission data 222.

 FIG. 3 is a diagram illustrating a flow for recovering an original data flow after receiving a plurality of flows and distributing them into detailed paths in the demultiplexing system according to the present invention.

When using a demultiplexing device to configure a switching system, a plurality of low-cost low-capacity transfer switching systems can be used to construct a large-capacity switching system. In this case, the minimum unit in which the order of transmission data should be maintained is called flow. In this case, the demultiplexer receives a plurality of flows and distributes them appropriately to a plurality of detailed paths or detailed switching paths, and then recovers the original data flow.

The transmission data labeling unit receives a data frame, which is transmission data, from the input port (step 310), and divides the data frames into flows, which are transmission units of traffic maintaining an order relationship, and adds order information of the flows to the transmission data ( Step 320). The load sharing unit checks / checks the traffic state of the detailed path where the data frame is transmitted (step 330), and determines the detailed path so that the transmission data is evenly distributed to the detailed paths. The detailed path distribution unit transmits the data labeling unit and the load distribution unit. Each of the transmission data and the determined detailed path number are input from the distribution data according to the detailed path (step 340). The allocated data frames are transmitted along each detailed path (step 350), and the transmission reordering unit rearranges the transmission data according to the transmission order relationship (step 360), and the transmission data scheduling schedules the aligned transmission data to the output port (step 370). ). The scheduled data frames are transmitted to each output port (step 380).

FIG. 4 is a conventional asynchronous demultiplexing method (FIG. 4A) of cells with multiple detailed delivery paths while maintaining a partial order in time of each detailed path for transferring data with Switched Connection Inverse Multiplexing for ATM (SCIMA). A method of efficiently distributing transmission data such as / packets / frames (FIG. 4B) is shown.

FIG. 5 shows a structure for improving the area and delay time for implementing a data distribution unit and a transmission data assembly which perform rearrangement by reducing the number of flows that maintain the order of data to be transmitted.

FIG. 6 is a diagram illustrating a process of combining a plurality of frame flows such that a transmission time interval between frames in one flow is greater than or equal to a predetermined time interval when combining and transmitting a plurality of frame flows according to the present invention.

Frame flow i transmitted switching maximum delay time difference between the path (worst case delay variance) to D if that _i When joining a plurality of flow of a frame flow frames in the i such that 2 * D _i or more intervals with a single flow of In this case, the transmission order of the frames of each flow is maintained. Therefore, when combining multiple frame flows together, each flow can maintain the transmission order. Such frame flow merging can be optimally solved using algorithms such as graph coloring and clique partitioning to find a complete graph. It can be implemented using a leaky bucket calendar queue or fair scheduler used in a traffic shaper. This means that the switch 210 of the detailed transmission path can be used in a system using a scheduler in which the maximum frame delay difference is guaranteed by using functions such as aging and old cell first (OCF) to avoid starvation. This is not possible with demultiplexed switching systems that use detailed switching paths that do not guarantee maximum frame latency. We show how to combine eight flows into one flow group.

FIG. 7 illustrates a process of combining a plurality of flows by aligning partially ordered flows that are not totally ordered with each other to be totally ordered, and using flow 1 711 and flow 2 ( 713 are each arranged in a flow 721 having a partial order relationship but reassembled and having a total order relationship.

FIG. 8 is a diagram illustrating the number of flow groups when merging flows in the demultiplexing apparatus of the present invention. The type of flow is 8 and the type of flow is 3 when the flow is merged.

9 is a diagram illustrating a comparison of the maximum queue usage of the service, the number of flows, and the reassembly unit when merging flows for transmission data according to the present invention.

The method of classifying the transmission data flow of the demultiplexing system by each input port and each output port is described.In the switch used as the detailed transmission path, the transmission data has the same path for each input and output. In this case, the flow can be classified by each input port and each output port of the data transmitted from the switch. In the case of determining the order of transmission data transmitted to different output ports in the transmission data distribution unit, the transmission data assembly receiving the transmission data has a difficulty in performing reordering by receiving only a part of the transmission sequences. In order to set up a single order of transmission data to the same output port, it is difficult to determine the total order of transmission data by communicating between different transmission data distribution units. Considering the implementation complexity, it is possible to design the transmission data flow classified by each input port and output port of the switch. As an example of means 1, a 16 * 16 switch may be classified into a flow of 16 * 16 = 256 according to each input / output combination.

By classifying the transmission data flow of the demultiplexing system into each input port, each output port, and transmission data type of the switch, a switching system that handles multiple transmission data types is usually point-to-point and point-to-point. It is necessary to process the transmission data type such as, broadcasting, etc., and if the switch converts other transmission data into point-to-point transmission data, it can be classified according to the flow of each input and output, but the transmission data type is one detailed path. When data is transmitted from the switch to the switch in different paths, different types of transmission data may not be maintained. Therefore, transmission data is classified according to each input port, output port, and transmission data type of the switch. You must use data flow. For example, in the case of a demultiplexed switching system using a 16 * 16 switch as a transmission path that can handle four types of transmission data types: point-to-point, point-to-point, broadcast, and control, a combination of input and output ports and transmission data types Can be classified as 16 * 16 * 4 = 1,024.

If the data flow of the demultiplexing system is classified into each input port, each output port, transmission data type and class, each transmission data in the case of a switching system that supports QoS and CoS recently There is a characteristic that the transmission order can be changed according to the class or priority of the. In the case of a demultiplexing system using such a switch as a transmission path, transmission data flows classified according to transmission data class or priority must be used. For example, in the case of a demultiplexing switching system that uses a 16 * 16 switch as a transmission path, which handles four types of transmission data types: point-to-point, point-to-multiple, broadcasting, and control, and can handle eight priority transmission data types. According to each combination of input / output port and transmission data type, it can be classified into 16 * 16 * 4 * 8 = 8,192 flows.

10 is a diagram showing a transmission data flow when the transmission data flow can be delivered in all the detailed paths in the demultiplexing apparatus according to the present invention.

The transmission data distribution unit 1010 receives the frame 1011 and distributes it to k switching plans 1031 of the detailed path 1030, and the transmission data assembly unit 1020 reassembles the received frame.

11 is a flow chart of transmission data when the transmission data flow of the present invention can be delivered in one detailed path. The transmission data distribution unit 1110 receives a frame 1111 from k switching plans of the detailed path 1130. Transfer to one switching plan 1131 and reassemble the frame in the transmission data reassembly unit 1120. To determine the detail path of a frame flow, one can use detail path = (switch output port number% number of detail paths in transmission data). here. a% b represents the remainder of a divided by b.

12 is a flow chart of transmission data when the transmission data flow of the present invention can be transmitted to some detailed paths in the entirety. The transmission data distribution unit 1210 receives the frame 1211 and switches k of the detailed paths 1230. Some of the switching plan 1231 is transmitted to the transmission data reassembling unit 1220 to reassemble the frame.

FIG. 13 shows a transmission data distribution unit 1310 in a demultiplexing switching system having i input ports and k detailed transmission paths, wherein a frame inputted through i input ports is transmitted to a transmission data labeling unit and a load sharing unit. The frame scheduling unit 1313 distributes the detailed paths through the distribution unit 1311.

By limiting the detail of the frame flow to some candidate detail set of all the detailed paths, the implementation complexity of the transmission data reassembly is reduced. The path through which the flow is transmitted is not pre-determined, but a limited subset of the transmission path is used, and a proper design can be made in consideration of load distribution of the detailed path and trade-off of the queue count of the transmission data reassembly unit. If the total number of detailed paths is k and if one flow is available among the l detailed paths smaller than k, the load distribution is possible to the l detailed paths, and the number of queues in the rearrangement portion is reduced by l / k times * Can be implemented with l . The information for determining the detailed path includes information such as the destination address, the switch input port number of the transmission data, the switch output port number of the transmission data, etc., which can be shared together by the transmission data distribution unit and the transmission data reassembly unit in the demultiplexing switching system. Combination prediction is possible, and when there are 8 detailed paths and 2 candidate detailed paths, the candidate detailed path set of the transmission data is set using the remaining value of the destination address of the transmission data = {(switch output port of the transmission data) Number% number of detailed transmission paths), (switch output port number of transmission data% number of detailed transmission paths) +1}.

FIG. 14 shows transmission data distribution in a demultiplexing switching system having i input ports and k detailed transmission paths, and time-divided transmission data transmitted to each input port in order to reduce an implementation area. The transmission data distribution unit 1410 is shown to perform, the connection unit 1411 is a transmission data labeling and load distribution unit 1413 for labeling and load distribution of the frame, to transmit the transmission data in the detailed path It is composed of a transmission data transfer queue 1415, which is a queue storing data.

FIG. 15 illustrates a transmission data distribution unit 1510 which performs time division of a subset of transmission data transmitted to each input port to distribute the transmission data in order to improve an implementation area and a delay time. In the connection unit 1511, the transmission data labeling unit, and the load distribution unit 1513, the transmission data are time-divided and distributed, and the transmission data delivery queue 1515 stores the transmission data to transmit the data in the detailed path.

FIG. 16 is a block diagram illustrating a transmission data distribution unit 1610 of the demultiplexing apparatus according to the present invention. The transmission data labeling unit 1611 adds a header to a frame input through an input port. The load distribution unit 1613 receives the load state information and grasps the state of the load in the detailed path in order to distribute the transmission data in the detailed path. The detailed path distribution unit 1615 connects the transmission data to the detailed transmission path according to the output of the load distribution unit 1613. The transmission data delivery queue 1617 manages detailed paths of transmission data to be transmitted next for each flow or flow group, and sequence numbers for each flow or flow group and detailed path.

FIG. 17 is a diagram illustrating an embodiment of a header added by the transmission data labeling unit 1611 of FIG. 16.

The transmission data labeling unit 1611 determines the header information of the current transmission data to be transmitted, and the information stored in the header of the transmission data includes the type of transmission data, the sequence number according to each flow, and the transmission data to be transmitted next in the same flow. It includes the detailed path number and backup information for error recovery. An embodiment of a CSIX frame header structure for demultiplexing is illustrated in FIG. 5. The transmission data header structure for demultiplexing includes the transmission data type, transmission data order, transmission data order in the detailed path, and detailed path numbers of a plurality of subsequent transmission data. The detailed path numbers of the next multiple transmission data of the transmission data header structure can be omitted from the transmission data header by predictive calculation using a frame identifier to reduce the bandwidth waste of the demultiplexer. . Types of transmission data in the transmission data header are classified into leader, painted, and leaf according to the transmission order as described above, and the transmission sequence number of transmission data for each flow and detailed path, It contains detailed path number of next transmission data in one flow and backup detail path number for recovery in case of error. The type of transmission data can be arbitrarily determined after dividing the transmission data set to be transmitted based on the appropriate length of the transmission data. The detailed path of the transmission data to be transmitted currently is input from the transmission data transmission queue 1617, and the detailed path number of the transmission data to be transmitted next is input from the load distribution unit 1613. And it manages the backup detailed path number of the most recently transmitted transmission data for each detailed path of each flow and uses it to construct the backup detail path number.

18 shows a basic structural diagram of a transmission data reassembling unit 1820 having k transmission detail paths and j output ports of the present invention, and parallel reassembly of data transmitted through a plurality of detailed transmission switching paths in the order of transmission. .

When the assembly input queue 1821 is composed of each detailed path and the same number and receives and outputs a frame from each detailed path, the transmission data sorting unit 1823 arranges the frames, and the transmission data scheduling unit 1825 receives each of the detailed paths. Output frames to the output port. Between the detailed path and the assembly input queue (1821), the connection unit 1827 serving as a demultiplexer transfers the transmission data.

FIG. 19 is a diagram showing the basic structure of the transmission data sorting unit 1831 of the transmission data reassembling unit 1820 of FIG. 18. The transmission data sorting unit 1620 uses the transmission data of the assembly input queue 1821. It exists in the same number as each input flow or flow group, and reassembles and outputs one flow or flow group in turn from multiple detailed paths. The leader of the transmission data sorting unit 1823, the transmission data detecting unit 1823-3 checks whether the leader frame has been delivered to the detailed path through the detail path selecting unit 1823-5, and the transmission data sorting unit 1823. ) Recovers the sequence of transmission data from the reader transmission data when a new flow starts or data connection error occurs during transmission. The transmission data output unit 1823-9 stores the predetermined detailed path of the next sequence data of the currently transmitted transmission data in the next transmission data detailed path storage queue 1823-7. The detailed path connection unit 1823-1 receives the transmission path of the data from the next transmission data detailed path storage queue 1823-7, and transfers the transmission data transmitted to the designated detailed path to the next transmission data output unit 1823-9. do. The frame realignment unit repeats the above processes.

20 illustrates an embodiment of a transmission data scheduling unit shown in FIG. 18. The transmission data scheduling unit 2025 that receives the flow for each output port (output ports 0 to j-1) is scheduled and outputs the flow to each output port.

FIG. 21 is a diagram illustrating an embodiment of a basic structure diagram of the first to jth transmission data scheduling units of the transmission data scheduling unit 2025 of FIG. 20.

The rearranged transmission data is scheduled through the structure scheduler for each flow characteristic and output port. The scheduled transmission data is stored in the reassembly output queue for each output port and forwarded. Each of the first to j th transmission data scheduling units includes a class scheduling unit 2025-1 for scheduling transmission data by class, point to point, multicasting, and broadcasting (for transmission data). A format scheduling unit 2025-3 for scheduling by type, such as broadcasting, control, and signaling, and an output port scheduling unit 2025-5 for scheduling transmission data for each destination output port. It consists of.

FIG. 22 is a diagram illustrating an embodiment of a structure of an assembly input queue 2221 of the transmission data reassembling unit 1820 of FIG. 18. The assembly input queue 2321-3 transmits the transmission data transmitted through the assembly connection unit 222-1 connecting the detailed paths and the assembly input queues (assembly input queue 1 to assembly input queue k). Represents a queue to be stored by group.

FIG. 23 illustrates an embodiment of a structure of an assembly input queue 2321 of the transmission data reassembling unit 1820 of FIG. 18 when a transmission path for each flow is predetermined. Assembly input queue 2321 is composed of a connection portion (2321-1) for connecting the transmission data input in the detailed path with each of the w assembly input queue (2321-3), such as the number of flows and parallel to each flow Print a set of reassembled transmission data.

FIG. 24 is a diagram illustrating a structure of an assembly input queue of a transmission data reassembly unit of FIG. 18 when using a candidate set of flow-by-flow transfer paths. FIG. The assembly input queue 2421 is composed of a connection portion 2421-1 connecting the transmission data inputted in the detailed path with each of the assembly input queues 2421-3 equal to the number of flows, and parallel to each flow. Print a set of reassembled transmission data.

As described above, according to the present invention, the present invention provides a demultiplexing system for providing the same service as using one large communication path by distributing and sequentially collecting digital transmission data using a plurality of low speed and low capacity paths. The present invention relates to an improvement means for efficiently implementing and circuit structures implementing the same. The demultiplexing means are used in various fields such as ATM multiplexing, demultiplexing of the AAL layer, and parallel multiple plane switching system. The demultiplexing means of the present invention has less implementation complexity, such as area and delay time, and implements circuits as compared to the conventional means. Since this is simple, it can be effectively used for the implementation of a large capacity demultiplexing system such as an IP packet, an ATM cell, and a frame.

In particular, de-multiplexing studies using multiple switching planes are being actively conducted to increase the transmission capacity of a switching system in response to the rapidly increasing Internet demand. Due to the extremely difficult and complicated complexity of the area and the like, the actual implementation is difficult, and thus, it is expected that the cost and effort of the large-capacity demultiplexing system can be reduced by using the means of the present invention.

1 is a diagram illustrating a basic structure of a demultiplexing switching system for distributing and transmitting transmission data such as a cell, a packet, or a frame into a plurality of transmission paths.

2 is a diagram illustrating a structure of a demultiplexed switching system supporting QoS or CoS according to the present invention.

 FIG. 3 is a diagram illustrating a flow for recovering an original data flow after receiving a plurality of flows and distributing them into detailed paths in the demultiplexing system according to the present invention.

FIG. 4 is a conventional asynchronous demultiplexing method (FIG. 4A) of cells with multiple detailed delivery paths while maintaining a partial order in time of each detailed path for transferring data with Switched Connection Inverse Multiplexing for ATM (SCIMA). A method of efficiently distributing transmission data such as / packets / frames (FIG. 4B) is shown.

FIG. 5 shows a structure for improving the area and delay time for implementing a data distribution unit and a transmission data assembly which perform rearrangement by reducing the number of flows that maintain the order of data to be transmitted.

FIG. 6 is a diagram illustrating a process of combining a plurality of frame flows such that a transmission time interval between frames in one flow is greater than or equal to a predetermined time interval when combining and transmitting a plurality of frame flows according to the present invention.

FIG. 7 is a diagram illustrating a method of aligning partially ordered flows having no total order relationship with each other to be totally ordered.

8 is a diagram illustrating the number of flow groups when merging flows in the demultiplexing apparatus of the present invention.

9 is a diagram illustrating a comparison of the maximum queue usage of the service, the number of flows, and the reassembly unit when merging flows for transmission data according to the present invention.

10 is a diagram showing a transmission data flow when the transmission data flow can be delivered in all the detailed paths in the demultiplexing apparatus according to the present invention.

11 is a flowchart illustrating a transmission data when the transmission data flow of the present invention can be delivered in one detailed path.

12 is a flowchart illustrating a transmission data when the transmission data flow of the present invention can be transmitted through some detailed paths.

FIG. 13 shows a transmission data distribution unit 1310 in a demultiplexing switching system having i input ports and k detailed transmission paths.

FIG. 14 shows transmission data distribution in a demultiplexing switching system having i input ports and k detailed transmission paths.

FIG. 15 illustrates a transmission data distribution unit 1510 which performs time division of a subset of transmission data transmitted to each input port to distribute the transmission data in order to improve an implementation area and a delay time.

16 is a diagram illustrating an embodiment of a block diagram of a transmission data distribution unit 1610 of the demultiplexing apparatus according to the present invention.

FIG. 17 is a diagram illustrating an embodiment of a header added by the transmission data labeling unit 1611 of FIG. 16.

18 shows a basic structural diagram of a transmission data reassembling unit 1820 having k transmission detail paths and j output ports of the present invention.

FIG. 19 is a diagram illustrating an embodiment of a basic structural diagram of a transmission data alignment unit 1831 of the transmission data reassembly unit 1820 of FIG. 18.

20 illustrates an embodiment of a transmission data scheduling unit shown in FIG. 18.

FIG. 21 is a diagram illustrating an embodiment of a basic structure diagram of the first to jth transmission data scheduling units of the transmission data scheduling unit 2025 of FIG. 20.

FIG. 22 is a diagram illustrating an embodiment of a structure of an assembly input queue 2221 of the transmission data reassembling unit 1820 of FIG. 18.

FIG. 23 illustrates an embodiment of a structure of an assembly input queue 2321 of the transmission data reassembling unit 1820 of FIG. 18 when a transmission path for each flow is predetermined.

FIG. 24 is a diagram illustrating a structure of a flow reordering unit input queue of the transmission data reassembling unit of FIG. 18 when using a candidate set of flow-by-flow transfer paths.

Claims (18)

Based on the input port number, output port number and type of the transmission data, the sets of transmission data having the order relation of transmission are distributed to a plurality of transmission paths, and the transmission data of out of order relationship is transmitted to the distributed transmission data. A transmission data distribution unit inserting a plurality of transmission paths information; A candidate detail paths among a plurality of detailed paths are determined based on at least one of a destination address, an input port number, and an output port number of the distributed transmission data, and transmission for transmitting the distributed transmission data through the candidate detail paths Data transmission department; And QoS and CoS, comprising: a transmission data assembly unit for reassembling the transmission data transmitted from the transmission data transmission unit based on the information of a plurality of transmission paths inserted into the transmission data in the transmission data distribution unit; Demultiplexing device of the exchange system to support the. According to claim 1, wherein the transmission data distribution unit A transmission data labeling unit that receives transmission data from an input port and divides the flow data into flows that maintain a sequence relationship and adds order information of the flows to the transmission data; A load distribution unit that checks a load state of the transmission data transmission unit and determines a detailed path so that the transmission data are evenly distributed to the detailed paths; A detailed path distribution unit which receives the transmission data and the determined detailed path numbers from the transmission data labeling unit and the load distribution unit, respectively and distributes the transmission data according to the detailed paths; And And a transmission data delivery queue for receiving and storing the transmission data and the determined detailed path numbers from the transmission data labeling unit and the load distribution unit, respectively. The method of claim 2, wherein the order information The information stored in the header of the transmission data includes the type of transmission data, the transmission order for each flow, the number of detailed paths for transmission of each transmission data in the same flow, and backup information for error recovery. Demultiplexing device of a switching system supporting QoS and CoS. The method of claim 1, wherein the transmission data assembly unit An assembly input queue configured to classify and store transmission data transmitted through the detailed paths according to an order-related flow and detailed paths; A transmission data sorting unit for sorting transmission data of the assembly input queue according to a transmission order relationship; And A transmission data scheduling unit for scheduling the aligned transmission data to an output port; And And a transmission data assembly output queue for storing the scheduled result. The method of claim 4, wherein the transmission data sorting unit A detailed path connection unit configured to receive the transmission data in the same flow stored in each assembly path in the assembly input queue and the transmission data received by receiving the transmission path of the transmission data; A detailed path extracting unit for extracting transmission data to be transmitted from the detailed path connecting unit and the detailed path thereof; A detailed path storing queue for storing the order of the transmission data extracted from the detailed path extracting unit and the detailed path to which the transmission data has been transmitted; And a reader transmission data detector for detecting a reader transmission data transmitted to the assembly input queue for the first time. The method of claim 4, wherein the transmission data scheduling unit The demultiplexing apparatus of the switching system supporting QoS and CoS, characterized in that the transmission data is scheduled by an input / output port, a class of transmission data, or a type of transmission data. (a) classifying data frames into transmission data sets having a transmission order relationship based on an input port number, an output port number, and a type; (b) inserting information on a plurality of transmission paths to which transmission data of late order is transmitted into the classified data frames; (c) determining detailed paths to be used for transmission among a plurality of detailed paths based on at least one of a destination address, an input port number, and an output port number of the data frames, and the plurality of transmission paths through the determined detailed paths to be used. Transmitting data frames comprising information; And (d) reassembling the frames received through the detailed paths to be used for the transmission based on information on a plurality of transmission paths included in the data frames. Demultiplexing method of exchange system. The method of claim 7, wherein step (a) And classifying the data frames by an input port or an output port for inputting / outputting the data frames. The method of claim 7, wherein step (a) And classifying the data frames according to types of input / output ports or transmission data for inputting and outputting the data frames. The method of claim 9, The transmission data type is a point-to-point communication method, a point-to-multipoint communication method or a broadcasting method, characterized in that the demultiplexing method of the switching system supporting QoS and CoS.  The method of claim 7, wherein step (a) And classifying the data frames into input / output ports for inputting and outputting the data frames, types of transmission data, or types of transmission data. The method of claim 7, wherein step (b) And decoupling the data frames such that the transmission time interval between the data frames is equal to or greater than a predetermined time interval. The method of claim 12, wherein step (b) And decoupling the data frames so that the transmission time interval between the data frames is equal to or greater than the difference * 2 of the maximum delay time of the transmission path. The method of claim 7, wherein step (c) The detailed path for transmitting the data frames is determined by a combination of information including an address of a destination for transmitting the data frame, a number of an input port (switch input port of the data frame), and an number of an output port. Demultiplexing method of exchange system supporting QoS and CoS 15. The method of claim 14, wherein step (c) In order to transmit data in one detail path, the detail path for transmitting the data frame is determined by the following equation, Detailed transmission path = (output port number% of detailed data transmission path) Here, a% b is a demultiplexing method of a switching system supporting QoS and CoS, characterized in that the remaining value of a divided by b.    15. The method of claim 14, wherein step (c) In order to transmit data in some of the detailed paths, the detailed path for transmitting the data frame is determined by the following equation, Set of detailed transmission paths = {(output port number% of detailed transmission paths of transmitted data frames), (output port number% of detailed transmission paths of transmitted data frames) +1} Here, a% b is a demultiplexing method of a switching system supporting QoS and CoS, characterized in that the remaining value of a divided by b. The method of claim 7, wherein step (d) And aligning data frames having a partial order relationship among the data frames into data frames having an overall order relationship. A computer-readable recording medium having recorded thereon a program for executing the method of any one of claims 7 to 17 on a computer.