KR20030042119A - Scheduler and scheduling method for optical burst switching routers - Google Patents

Abstract

PURPOSE: A scheduler for an optical burst switching router and a method thereof are provided to minimize burst data loss by performing a scheduling in arrival order of burst data. CONSTITUTION: Channel information including arrival time information, offset time information and burst data length information of a header packet into which a burst data is inputted is received(41). Processing order information of a scheduling is generated on the basis of the arrival time information of burst data generated on the basis of the arrival time information of the header packet and the offset time information(42). An optical switch switching duration information is generated on the basis of the arrival time information and length information of the burst data(43). Output channel information is generated to output burst data received from an optical switch on the basis of a difference between a previously reserved activation-end time of the optical switch and an arrival time of new burst data to a transmission channel of an optical transmission path(44). Control information for controlling an optical switch fabric is generated on the basis of the processing order information of scheduling, the switching duration information of optical switch and the output channel information(45).

Description

Scheduler for optical burst switching router and method thereof {Scheduler and scheduling method for optical burst switching routers}

The present invention relates to a scheduler and a method for determining a data transmission channel from the core and edge router of the optical burst switching network to the next node.

The explosive increase in the amount of data sent to Internet users and the current network demands more bandwidth. The advent of dense-wavelength division multiplexing (DWDM) technology is a solution to overcome the bandwidth problem occurring in current optical networks. A single high-density wavelength-division multiplexed fiber has the ability to transmit tens of terabits of data per second. Optical switching technology using high-density wavelength division multiplexed fiber can be divided into optical circuit switching, optical packet switching, and optical burst switching. Optical circuit switching requires two reservations. Send a setup message to reserve the channel before sending data from the source node to the destination node. The setup message passes through the intermediate node and reserves the channel for data transmission. When a setup message arrives at the destination node, an ACK message is sent backward to indicate that the channel is successfully reserved. The source node checks the acknowledgment message before sending the data. This switching method has a disadvantage in that bandwidth utilization is low because different source nodes or destination nodes do not share the bandwidth of the optical transmission path.

Optical packet switching transmits the header packet and the data packet together to the destination node without setting up the optical transmission path before sending the data. Since optical packet switching has a store-and-forward method, the header packet transmitted from the source node determines the optical transmission path with information about the destination node for each intermediate node, so it is necessary to temporarily store the data packet while the header packet is processed. do. This switching method has a disadvantage in that an optical buffer is required for temporarily storing data packets for each intermediate node and for synchronizing each data packet.

Optical burst switching technology is a new technology that takes advantage of the above-mentioned optical circuit switching and optical packet switching and complements the disadvantages. Using a one-way reservation method, the source node transmits data without waiting for an ack message, which has a short duration between nodes. Also, after separating the header packet and the data packet, the data packet is stored in the electric node's electric buffer after the header packet processing time for each node and then transmitted. Therefore, the optical buffer is not required for each intermediate node.

However, optical burst switching technology also has technical problems. First, in optical burst switching, the length of burst data is variable and relatively large compared to the data of general optical packet switching. Therefore, there is a problem in that the loss of data generated when channel reservation is wrong is large. Second, optical burst switching In this case, the reservation of the data channel must be maintained only for a certain period of time, thereby causing a loss of data when strict time management is not performed. In addition, third, the most time-consuming part to set the optical transmission path is the channel scheduling of the data burst, so there is a problem that a scheduler using a fast and simple scheduling algorithm is required.

It is an object of the present invention to provide a scheduler and scheduling method for an optical burst switching network router with a simple structure and efficiency.

1 illustrates an optical burst switching network concept.

FIG. 2 illustrates the concept of header packet and burst data transmission between the optical burst switching network nodes of FIG.

3 shows a concept of a scheduler for an optical burst switching router.

4 is a flowchart illustrating a scheduling method in an optical burst switching router according to the present invention.

5 shows a functional block diagram of a scheduler in an optical burst switching router according to the present invention.

6 shows a concept of a header packet and burst data entering an optical burst switching network.

7 illustrates a concept of scheduling according to a conventional header packet arrival order.

8 illustrates a concept of scheduling in burst data arrival order according to the present invention.

9 is a diagram illustrating an algorithm for determining an output channel of a conventional scheduler.

10 is a diagram illustrating an algorithm for determining an output channel of a scheduler according to the present invention.

11 shows an example of a data frame input to a scheduler according to the present invention.

12 shows an example of a data frame for channel determination in the scheduler according to the present invention.

Figure 13 shows an example of a data frame delivered to the optical switch fabric according to the present invention.

The scheduling method in the optical burst switching router according to the present invention for solving the above problems comprises the steps of: (a) receiving channel information including arrival time information of the header packet, offset time information, length information of the burst data, (b) Generating the arrival time information of the burst data based on the arrival time information and the offset time information of the header packet, and generating scheduling processing order information by determining a processing order of scheduling based on the arrival time information of the burst data; (c) generating optical switch switching duration information based on the arrival time information and the length information of the burst data; (d) generating output channel information by determining an output channel for outputting burst data input from the optical switch; And (e) processing sequence information of the scheduling, switching duration information of the optical switch, and output channel information. Power take characterized by including the step of controlling an optical switch fabric. The step (b) may include generating arrival time information of burst data by adding an offset time to an arrival time of the header packet, and determining a processing sequence of scheduling according to the arrival time order of the burst data. In the step (c), the optical switch operation start time information is generated to advance the time required for switching the optical switch to the arrival time of the burst data, and the length of the burst data is added to the arrival time of the burst data. Generating end time information of the optical switch;

The channel information further includes input channel information into which burst data is input, and the control signal for controlling the optical switch fabric includes the input channel information, output channel information, switch operation start time information, and switch operation end time information. It can be characterized.

Also according to the present invention for solving the above problems The method for determining the output channel to output the burst data input from the optical switch is to (a) obtain the difference between the optical switch operation start time and the optical switch operation end time previously reserved for each transmission channel of the optical transmission path, and then switch for each channel. Generating interval information, (b) pairing each transmission channel of the optical transmission path by two and comparing the switching interval information of the paired transmission channels to select transmission channels having a smaller switching interval than the other party; (c) repeating step (b) until one transport channel having the smallest switching interval is selected among the transport channels of the optical transmission path; and (d) replacing the transport channel selected in step (c) as an output channel. Determining and generating output channel information.

In addition, the scheduling apparatus in the optical burst switching router according to the present invention for solving the above problems receives the channel information including the arrival time information, offset time information, the burst information length information of the header packet to which burst data is input, Determination of arrival order of generating scheduling time sequence information by generating arrival time information of burst data based on arrival time information and offset time information of the header packet, and determining a processing order of scheduling based on arrival time information of the burst data. An output channel duration calculator configured to determine an operation start time and an operation end time of the optical switch based on the arrival time information and the length information of the burst data, and to generate the optical switch switching duration information; Pre-scheduled optical switch end time and arrival of new burst data An output channel determiner for determining output channels for outputting burst data input from the optical switch and generating output channel information based on the difference therebetween; and processing sequence information of the scheduling, switching duration information of the optical switch, and output channel information. And an optical switch fabric control signal generation unit configured to generate a control signal to control the optical switch fabric and provide the control signal to the optical switch fabric. In addition, the arrival order determination unit The arrival time information of the header packet is added to the arrival time of the header packet to generate arrival time information of the burst data, and the processing sequence of the scheduling may be determined according to the arrival time order of the burst data. The optical switch operation start time information is generated to advance the time required for switching the optical switch to the arrival time of the burst data, and the length of the burst data is added to the arrival time of the burst data to end the operation of the optical switch. The time channel information may be generated. The output channel determination unit obtains a difference between an operation start time of the optical switch and an optical switch operation end time previously reserved for each transmission channel of the optical transmission path. Information is generated, and each transmission channel of the optical transmission path is paired with each other. Outputs the transport channel selected as one transport channel having the smallest switching gap among the transport channels of the optical transmission path by comparing transport interval information of two transport channels paired with each other and selecting transport channels having a smaller switching gap than the other. It may be characterized by determining as a channel.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 illustrates an optical burst switching network concept. The optical burst switching network 14 is composed of several edge routers 11, core routers 12, and optical transmission paths 13. Reference numeral 15 is a kind of network other than the optical burst switching network. Here, the edge router 11 is referred to as an ingress edge router when located at the source node in terms of data, and is called an egress edge router when located at the destination node. Each node constituting the optical burst switching network has functions of both the edge router 11 and the core router 12 according to location and purpose. The edge router 11 has a function of assembling / decomposing other types of data into burst data in the form of transmission data of the optical burst switching network by connecting to the non-optical burst switching network 15.

FIG. 2 illustrates the concept of header packet and burst data transmission between the optical burst switching network nodes of FIG. The burst data assembled from the data of the non-optical burst switching network 15 is transmitted from the source node to the destination node via the optical transmission path 13. The source node and the destination node are composed of the edge router 11, and the nodes in the optical transmission path connecting the source node and the destination node are composed of the core router 12. In the optical transmission path connecting the node and the node, all of the header packet 21 and the burst data 22 are transmitted. The header packet 21 and burst data 22 transmitted from one node to another node are delivered with a specific channel. When the header packet 21 arrives at any node, the burst data 22 accordingly arrives at any node after the offset time 23 passes. The offset time 23 is variable according to each header packet 21.

3 shows a concept of a scheduler for an optical burst switching router. Meanwhile, FIG. 11 shows a preferred embodiment of a data frame input to a scheduler according to the present invention. FIG. 12 shows an example of a data frame for channel determination in the scheduler according to the present invention. Shows an example of a data frame transmitted to an optical switch fabric. Hereinafter, the present invention will be described with reference to FIGS. 11, 12, and 13 together.

The channel information entering the scheduler 31 in FIG. 3 has a data frame format shown in FIG. 11 and includes information about an input channel, a header packet arrival time, an offset time, and a burst data length. The control signal exiting from the scheduler 31 is composed of input channel information, output channel, optical switch operation start time, optical switch operation end time, and the like of burst data using a scheduling algorithm with input channel information, and then the data shown in FIG. 13. The frame format is transmitted to the optical switch fabric 32.

4 is a flowchart illustrating a scheduling method in an optical burst switching router according to the present invention. First, channel information including arrival time information, offset time information, and burst information length information of a header packet into which burst data having a data frame format shown in FIG. 11 is input is received 41. Thereafter, the processing sequence information 42 for scheduling is generated based on the arrival time information of the burst data generated based on the arrival time information and the offset time information of the header packet. After generating the optical switch switching duration information based on the arrival time information and the length information of the burst data (43), the difference between the optical switch operation end time previously reserved for the transmission channel of the optical transmission path and the arrival time of the new burst data is determined. In operation 44, output channel information for outputting burst data received from the optical switch is generated. Finally, the control information for controlling the optical switch fabric is generated 45 based on the processing sequence information of the scheduling, the switching duration information of the optical switch, and the output channel information.

5 shows a functional block diagram of a scheduler in an optical burst switching router according to the present invention. The scheduler 31 is internally composed of an arrival sequence determiner 51 of the data channel, an output channel duration calculator 52, an output channel determiner 53, and an optical switch fabric control signal generator 54. . The arrival order determination unit 51 of the data channel has a function of calculating the arrival time of the burst data 22 and determining the order in order to preferentially process the burst data 22 having a fast arrival time. The arrival order of the header packets 21 entering the various input ports and the corresponding arrival order of the burst data 22 do not coincide because the offset time 23 varies variably. When the arrival rate of the burst data 22 is high even though the arrival order of the header packet 21 is late, burst data loss occurs if the channel of the burst data is reserved according to the arrival order of the header packet.

6 shows a concept of a header packet and burst data entering an optical burst switching network. Since the headers are transmitted from the left side to the right side of FIG. 6, the headers arrive at the node in the order of the header 3, the header 1, and the header 2.

7 illustrates a concept of scheduling according to a conventional header packet arrival order. When the data as shown in FIG. 6 is transmitted, the header packet is processed in the order of the header 3, the header 1, and the header 2 because the processing is performed according to the arrival order of the header packet 21. Assuming that the processing time of all headers is the same, since the processing is performed as in FIG. 7, since burst 2 arrives at the node while header 2, the third header packet 21, is processed in the scheduler 31, the data of burst 2 Is lost. This occurs because the arrival order of the header packet 21 and the arrival order of the burst data 22 are inconsistent.

8 illustrates a concept of scheduling in burst data arrival order according to the present invention. In the present invention, since the packet header is processed according to the arrival order of the burst data 22, it proceeds in the order of header 2, header 1, and header 3. If all headers are assumed to have the same processing time, the processing is performed as in the case of FIG. 8, and since burst 3 arrives after the third header packet 21 is processed in the scheduler 31, burst 3 is not lost. Can do scheduling. Therefore, it can be seen that it is an optimal method to determine and schedule the processing order based on the arrival order of the burst data 22. By using the arrival order determining unit 51 of the data channel according to the present invention, the occurrence rate of data loss is minimized. I can do it.

The output channel duration calculator 52 has a function of determining the operation time of the switch in the optical switch fabric. The arrival time of the burst data can be calculated using Equation 1, and the processing order is determined according to the arrival time of the burst data using Equation 1. The operation start time of the optical switch is determined in consideration of the arrival time of the burst data and the switching time of the optical switch. The optical switch operation end time can be obtained by using Equation 2 with information on the length of the data burst included in the header packet. Therefore, by using the output channel duration calculator 52 according to the present invention, the optical switch is operated only while the burst data passes through the optical switch fabric, thereby maximizing channel utilization efficiency.

(Burst Data Arrival Time) = (Header Packet Arrival Time) + (Offset Time)

(Optical switch operation end time) = (optical switch operation start time) + (burst data length)

The output channel determination unit 53 has a function of determining a transmission channel for transmitting burst data to the next node. Using Equation 1 and Equation 2 above, an operation start time and an operation end time of the optical switch for switching burst data in the optical switch fabric can be obtained, respectively. The reserved channel information is stored in the register of the output channel determination section 53 with the frame format of FIG. Since the channel utilization efficiency can be maximized by minimizing the interval with the previously reserved channel, the channel with the minimized interval can be found by calculating the difference between the optical switch operation end time of the previously reserved channels and the arrival time of the new burst data. have. Equation 3 is to obtain the interval between the reserved channel for the output channel determination and the new channel to maximize the channel utilization efficiency when selecting the channel with the minimum interval between the burst data.

(Interval between channels) = (optical switch operation start time of new burst data)-(optical switch operation end time of reserved burst data)

9 is a diagram illustrating an algorithm for determining an output channel of a conventional scheduler. In order to determine the burst data transfer channel, the output channel determiner 53 stores the optical switch operation end time information of each wavelength previously reserved in the frame format of FIG. 12 in a temporary register as shown in FIG. When the header packet 21 arrives and reserves a transmission channel for the new burst data 22, the operation start time of the optical switch can be obtained using Equation 1. In STAGE 1, the optical switch operation end time of each wavelength stored in the register and the optical switch operation start time of the new burst data are calculated using Equation 3 and then stored in the register. In the conventional scheduler, the channel intervals of the first and second wavelengths are compared, and then the smaller channel intervals are stored in the register as in STAGE 2, and the comparison is repeated by the number of channels to finally determine the channel having the smallest channel interval. 9 illustrates a concept of a series of processes for determining a transport channel in a conventional scheduling scheme when there are 8 transport channels per unit link. As shown in the figure, when eight transport channels are used per unit link, eight STAGEs are used, so a simpler and faster scheduling algorithm is required.

10 is a diagram illustrating an algorithm for determining an output channel of a scheduler according to the present invention. In order to determine the burst data transfer channel, the output channel determiner 53 stores the optical switch operation end time information of each wavelength previously reserved in the data frame format of FIG. 12 in a temporary register as shown in FIG. When the header packet 21 arrives and reserves a transmission channel for the new burst data 22, the operation start time of the new optical switch can be obtained using Equation 1. In STAGE 1, the optical switch operation end time of each wavelength stored in the register and the optical switch operation start time of the new burst data are calculated using Equation 3 and then stored in the register. In STAGE 2, the spacing between the channels stored in the register is compared for each two channels using dichotomy, and the values with smaller spacing are stored in the register. 10 shows a concept of a series of processes for determining a transport channel in the scheduler according to the present invention when there are 8 transport channels per unit link. As shown in FIG. 10, four STAGEs are used when eight transport channels are used per unit link. Therefore, when using the scheduler according to the present invention it can be seen that the processing speed is twice as fast as the conventional channel determination method. When the transmission channel is determined by the channel determination method, the frame data of FIG. 12 is newly updated with the determined data.

The optical switch fabric control signal generation unit 54 has a function of generating a signal for optical switch control using the information generated by the scheduling algorithm and transferring the signal to the optical switch fabric. The control signal transmitted to the optical switch is composed of an input channel, an output channel, a switch operation start time, and a switch operation end time, and have a frame format of FIG. 13.

Meanwhile, the above-described embodiments of the present invention can be written as a program that can be executed on a computer. And, it can be implemented in a general-purpose digital computer for operating the program using a medium used in the computer. In addition, the data and its data structure used to implement the present invention or embodiments of the present invention can be recorded on a medium used in a computer. The media may be stored such as magnetic storage media (e.g., ROM, floppy disk, hard disk, etc.), optical reading media (e.g., CD-ROM, DVD, etc.) and carrier waves (e.g., transmission over the Internet). Media.

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

According to the present invention, since the scheduling is performed according to the arrival order of burst data rather than the arrival time of the header packet, the loss of burst data can be minimized. In addition, it has the advantage that the channel utilization efficiency can be maximized by determining the channel which minimizes the gap between the previously reserved burst data and the newly reserved burst data as the output channel.

Claims (13)

A scheduling method in an optical burst switching router, (a) receiving channel information including arrival time information of the header packet, offset time information, and length information of burst data; (b) generating the arrival time information of the burst data based on the arrival time information and the offset time information of the header packet, and determining scheduling processing order based on the arrival time information of the burst data to generate scheduling processing sequence information. step; (c) generating optical switch switching duration information based on arrival time information and length information of the burst data; (d) generating output channel information by determining an output channel for outputting burst data received from the optical switch; And and (e) receiving the processing sequence information of the scheduling, switching duration information of the optical switch, and output channel information to control the optical switch fabric. The method of claim 1, wherein step (b) And generating an arrival time information of burst data by adding an offset time to an arrival time of the header packet, and determining a scheduling procedure according to the arrival time sequence of the burst data. The method of claim 1, wherein step (c) The optical switch operation start time information is generated to advance the time required for switching the optical switch to the arrival time of the burst data, and the length of the burst data is added to the arrival time of the burst data to end the operation of the optical switch. Scheduling method for generating time information. The method of claim 1, wherein step (d) The difference between the operation start time of the optical switch and the operation time of the optical switch reserved in advance in each transmission channel of the optical transmission path is obtained to generate switching interval information for each channel, and the respective transmission channels of the optical transmission path are paired in pairs. The transmission channel selected as one transmission channel having the smallest switching interval among the transmission channels of the optical transmission path is determined as an output channel by comparing the switching interval information of two constructed transmission channels and selecting a transmission channel having a smaller switching interval than the other channel. The scheduling method, characterized in that for generating the output channel information through the process. The method of claim 1, The channel information further includes input channel information into which burst data is input. The control signal for controlling the optical switch fabric includes the input channel information, output channel information, switch operation start time information, switch operation end time information. In the method for determining the output channel to output the burst data received from the optical switch, (a) generating switching interval information for each channel by obtaining a difference between an operation start time of the optical switch and an optical switch operation end time previously reserved for each transmission channel of the optical transmission path; (b) pairing each transmission channel of the optical transmission path by two and comparing the switching interval information of the paired two transmission channels to select transmission channels having a smaller switching interval than the other party; (c) repeating step (b) until one transport channel having the smallest switching interval is selected among the transport channels of the optical transmission path; And (d) determining the transmission channel selected in step (c) as an output channel to generate output channel information. A scheduling apparatus in an optical burst switching router, Receives channel information including arrival time information, offset time information, and burst information length information of a header packet into which burst data is input, and arrives time information of burst data based on arrival time information and offset time information of the header packet. An arrival sequence determiner for generating scheduling sequence information based on the arrival time information of the burst data; An output channel duration calculator configured to generate optical switch switching duration information based on the arrival time information and the length information of the burst data; An output channel determiner configured to determine an output channel for outputting burst data received from the optical switch and to generate output channel information; And And an optical switch fabric control signal generation unit configured to control the optical switch fabric by receiving the processing sequence information of the scheduling, switching duration information of the optical switch, and output channel information. The method of claim 7, wherein the arrival order determining unit And generating an arrival time information of burst data by adding an offset time to an arrival time of the header packet, and determining a processing order of scheduling according to the arrival time order of the burst data. The method of claim 7, wherein the output channel duration calculation unit The optical switch operation start time information is generated to advance the time required for switching the optical switch to the arrival time of the burst data, and the length of the burst data is added to the arrival time of the burst data to end the operation of the optical switch. Scheduling apparatus for generating time information. The method of claim 7, wherein the output channel determiner The switching interval information is generated for each channel by obtaining the difference between the operation start time of the optical switch and the optical switch operation end time previously reserved for each transmission channel of the optical transmission path, and pairing each transmission channel of the optical transmission path by two pairs. The transmission channel selected as one of the transmission channels having the smallest switching interval among the transmission channels of the optical transmission path through the process of selecting the transmission channels having a smaller switching interval by comparing the switching interval information of the two paired transmission channels. Scheduling apparatus, characterized in that determined by. In the device for determining the output channel to output the burst data received from the optical switch, A switching interval information generation unit for obtaining a difference between the operation start time of the optical switch and the operation end time of the optical switch reserved in advance in each transmission channel of the optical transmission path and generating switching interval information for each channel; And Pairing each transmission channel of the optical transmission path by two, comparing the switching interval information of the paired transmission channels, selecting transmission channels having a smaller switching interval, and selecting one transmission channel having the smallest switching interval. And an output channel selector for generating output channel information. A computer-readable recording medium having recorded thereon a program for executing the method of any one of claims 1 to 6. Channel information including arrival time information, offset time information, and length information of burst data of a header packet into which burst data is input; Scheduling processing sequence information by determining a processing sequence of scheduling based on arrival time information of burst data generated based on arrival time information and offset time information of the header packet; Optical switch switching duration information generated based on arrival time information and length information of the burst data; Output channel information for determining an output channel for outputting burst data received from an optical switch; And Computer-readable recording in which channel information data having a data field structure relating to control information for controlling the optical switch fabric generated based on the processing sequence information of the scheduling, switching duration information of the optical switch, and output channel information is recorded. media.