JP2004357005A - Method for transmitting data with different transmission priority, its transmission processor and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the use efficiency of a transmission band by guaranteeing the highest transmission priority to surely transmit data and efficiently transmitting even data of low transmission priority without delaying the data in particular, by a simple constitution. <P>SOLUTION: A transmission priority determining part 11 determines transmission priorities of respective input packet strings of a plurality of types of transmission priorities, and a packet header processing part 14 determines a part between packets of input packet strings of the highest transmission priority. By processing a packet storing and outputting parts 12 and 13, a packet header preparing part 15, a packet storing and outputting part 16 and an output control part 17, there are arranged respective packets of input packet strings of transmission priorities lower than the highest transmission priority between the packets to generate a new packet string composed of the highest transmission priority and the low transmission priorities, transferring (transmitting) the new packet string to a communication line network. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to transmission priority control of transmission data in traffic management control for avoiding congestion in a data communication line network, and particularly, executes transmission priority control of variable-length data (variable data amount / packet). The present invention relates to a method of transmitting data having different transmission priorities, a transmission processing device thereof, and a program.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a transmission amount (line capacity) in a communication network including a communication line network and a connection device has been sequentially increased.
[0003]
On the other hand, effective use of communication network resources, in other words, efficient data transmission, has been demanded in response to deterioration of communication efficiency of a communication network due to recent increase in traffic volume.
[0004]
The deterioration of the transmission efficiency of the communication network includes a delivery delay in a relay device (node) such as a routing device in a packet communication network (for example, Transmission Control Protocol / Internet Protocol (TCP / IP)), a variation in delivery delay, and There are disposal rates.
[0005]
Conventionally, in this type of packet communication line network, transmission priority control of transmission packets in traffic management control for avoiding congestion is performed. The transmission priority control improves the efficiency of band use in the communication network.
[0006]
In IP packet transmission of variable-length data and the like, “QoS / CoS” (Quality of Service / communication quality) and “DiffServ” (Differentiated Service / user communication traffic type correspondence) are related to transmission priority control. ), SLA (Service Level Agreement / contract regarding communication service content of user), “IntServ” (Integrated service / packet transmission by bandwidth reservation), and the like are known.
[0007]
In such transmission priority control in QoS and Diffserv, the utilization efficiency of the communication band may decrease depending on the data length of the packet. For example, when the transmission packet length is short at the high transmission priority and the interval between the transmission packets is shorter than the transmission packet length at the low transmission priority, the transmission packet with the high transmission priority is transmitted first ( Sent).
[0008]
Therefore, the transmission packet of the low transmission priority is kept waiting for transmission until the transmission of the transmission packet sequence of the high transmission priority is completed. That is, transmission delay of a transmission packet having a low transmission priority occurs. In other words, the utilization efficiency of the communication band is reduced.
[0009]
As a proposal for improving the reduction in communication band utilization efficiency in this type of transmission priority control, when a call connection request is received from a terminal device, the gatekeeper device permits the call connection request according to the network load. There is a proposal to determine whether or not this would prevent overloading in the communication network and prevent interference with other communications.
[0010]
Furthermore, in this proposal, permission for a call connection request is permitted only from the terminal device for which the priority flag is set. In addition, it determines whether or not to permit the call connection corresponding to the estimated communication network load state and the transmission priority set in the terminal device. As a result, appropriate call connection control corresponding to the type of the terminal device is executed (Patent Document 1).
[0011]
[Patent Document 1]
Japanese Patent Application Laid-Open No. 2003-87312 "Gatekeeper device and communication system"
[0012]
[Problems to be solved by the invention]
The above conventional example has the following disadvantages (1) and (2).
(1) The former of the above-mentioned conventional example has a drawback that transmission delay of a transmission packet with a low transmission priority occurs, and communication band utilization efficiency is reduced.
(2) In the latter conventional example (Patent Document 1), appropriate call connection control corresponding to the type of terminal device can be executed, and similarly to the former example of the conventional example, transmission with low transmission priority is performed. There is a drawback that packet transmission delay occurs and communication band utilization efficiency decreases.
[0013]
The present invention has been made in view of the above circumstances, and guarantees, by a relatively simple system configuration, a plurality of types of transmission priorities, the highest transmission priority of transmission data such as packets, and a low transmission priority. Transmission method for transmitting data with different transmission priorities, which can efficiently transmit the transmission data without special delay, and consequently improve the utilization efficiency of the transmission band in the communication network. The purpose is to provide devices and programs.
[0014]
[Means for Solving the Problems]
In order to achieve the above object, a method of transmitting data having different transmission priorities according to the present invention includes, in each of a plurality of types of transmission priorities, determining a non-data section of an input data sequence having the highest transmission priority. In the determined no-data section, each data in the input data sequence having a lower transmission priority than the highest priority transmission order is arranged, and a new transmission priority including the highest priority transmission order and the lower transmission priority is guaranteed. Generating a new data sequence and transmitting the new data sequence to the communication network from the device output side.
[0015]
According to the data transmission method having different transmission priorities of the present invention, when executing transmission priority control of transmission data (for example, packets) in traffic management (control) for avoiding congestion in a data communication network, for example. In addition, by using a relatively simple system configuration, transmission data of a plurality of transmission priorities (for example, two or more transmission priorities including high and low and three or more transmission priorities including high, medium and low) are transmitted to the highest priority. Transmission can be performed while guaranteeing the priority transmission priority, and transmission data with low transmission priority can be transmitted efficiently without any special delay. In other words, the utilization efficiency of the transmission band in the communication network is improved.
[0016]
As a preferred aspect of the method for transmitting data having different transmission priorities of the present invention, in the step of generating the new data sequence, each data in the low transmission priority input data sequence can be arranged in the non-data section. Then, when each data in the input data sequence of the low transmission priority can be arranged in this determination, each data in the input data sequence of the low transmission priority is determined as the highest priority transmission order. It is arranged in the non-data section of the input data sequence, and then a new data sequence is generated which has the highest priority transmission order and the low transmission priority by this arrangement.
[0017]
In this preferred aspect, a new data sequence in which each data in the input data sequence of the low transmission priority is arranged in the non-data section of the input data sequence of the highest transmission priority can be quickly and easily set to, for example, the low transmission priority. It is generated without dividing the rank input data.
[0018]
Further, as a preferable mode in the transmission method of data having different transmission priorities of the present invention, in the determined no-data section, each data in an input data sequence having a lower transmission priority than the highest priority transmission order is arranged. In the step of generating a new data sequence, it is determined whether or not each data in the low transmission priority input data sequence can be arranged in the non-data section. When the respective data in the data sequence cannot be arranged, the respective data in the input data sequence having the lower transmission priority are divided and arranged, and then the highest priority transmission order by this arrangement and the lower priority transmission order are determined. It is characterized in that a new data string consisting of transmission priorities is generated.
[0019]
In this preferred aspect, even when each data in the input data sequence of the low transmission priority cannot be arranged in the non-data section of the input data sequence of the highest transmission priority, a new data sequence is generated by the division and arrangement. Is done.
[0020]
Further, as a preferred embodiment of the transmission method of data having different transmission priorities of the present invention, when each data in the input data sequence of the low transmission priority is divided and arranged, one type or a plurality of types may be used. Each data in the input data sequence of the low transmission priority is divided and arranged.
[0021]
As a preferable mode of the transmission method of the data having different transmission priorities, the same data may be assigned to each of the one type or each of the plurality of types of low-priority input data sequences that are divided and arranged. It is characterized by adding and arranging data related to a header that unifiedly indicates an input data string.
[0022]
Further, the input data sequence is a packet sequence having a data structure including a header area and a payload data area of variable length or fixed length.
[0023]
The above-mentioned transmission priorities include, for example, SLA (contract for communication service contents with a Service Level Agreement user), QoS (Quality of Service / communication quality), Diffserv (Differentiated Service / user communication traffic type correspondence). ), And IntServ (Integrated service / packet transmission by bandwidth reservation).
[0024]
In this preferred aspect, each data in one type or a plurality of types of input data sequences of low transmission priority is divided and arranged, so that it is possible to cope with various data configurations.
[0025]
A data transmission processing device according to the present invention for achieving the above object transmits data to which a plurality of transmission priorities are set, and determines the priorities of the plurality of transmission priorities in respective input data strings. Priority determining means for determining a non-data section of an input data sequence having the highest priority transmission order in the transmission priority determining means, and a non-data section determined by the non-data section determining means. In the section, each data in the input data sequence having the lower transmission priority than the highest priority transmission order is arranged, and a new data sequence that guarantees the transmission priority consisting of the highest priority transmission order and the lower transmission priority is generated. A new data string generating means, and a new data string transmission for transmitting the new data string by the new data string generating means to the communication network from the output side of the transmission processing device to the communication network. Characterized in that it comprises a means.
[0026]
A determination processing unit that determines whether or not each data of the input data sequence of the low transmission priority can be arranged in the non-data section determined by the non-data section determination unit; When each data of the input data sequence of the low transmission priority can be arranged, the arrangement processing unit which arranges each data in the input data sequence of the low transmission priority in the non-data section of the input data sequence of the highest priority transmission order And a generation processing unit that generates a new data string including the highest priority transmission order and the low transmission priority in the arrangement by the arrangement processing unit.
[0027]
Further, a determination processing unit that determines whether or not each data of the input data sequence of low transmission priority can be arranged in the non-data section determined by the non-data section determination unit. An arrangement processing unit for dividing and arranging each of the low transmission priority input data strings when each data of the low transmission priority input data string cannot be arranged, and a top priority by the arrangement in the arrangement processing unit And a generation processing unit that generates a new data sequence having a transmission order and a transmission priority lower than the highest priority transmission order.
[0028]
Further, the data transmission processing device is arranged on an output side connected to a communication network.
[0029]
In the data transmission processing device according to the present invention, the transmission data (packet) having the highest priority transmission order is reliably (guaranteed) by a relatively simple system configuration, similarly to the above-described method for transmitting data having different transmission priorities. And transmission data of low transmission priority can be transmitted efficiently without any special delay, thereby improving the utilization efficiency of the transmission band in the communication network.
[0030]
A program of the present invention for achieving the above object includes a step of determining a non-data section of an input data string of the highest priority transmission order in each of input data strings of a plurality of transmission priorities; Determining whether each data of the input data sequence of the low transmission priority can be arranged; and in this determination, when each data of the input data sequence of the low transmission priority can be arranged, In the non-data section of the input data string of the above, a step of adding and arranging the data relating to the header indicating uniformly the same input data string to each data of the input data string of the low transmission priority, Generating a new data sequence consisting of the highest-priority transmission order and the low-priority transmission order according to the arrangement; and transmitting the new data sequence to the communication network on the device output side. It is intended to execute the steps of al transmitted to the computer.
[0031]
A program of the present invention for achieving the above object includes a step of determining a non-data section of an input data string of the highest priority transmission order in each of input data strings of a plurality of transmission priorities; Determining whether or not each data of the low-priority input data sequence can be arranged; and in this determination, when the respective data of the low-transmission-priority input data sequence cannot be arranged, In the non-data section of the input data sequence, the data relating to the header that uniformly indicates that the input data sequence is the same as the data of one type or a plurality of types of input data sequences of low transmission priority that are divided. , And generating a new data string having the highest priority transmission order and a lower transmission priority than the highest priority transmission order. A step that is intended for executing the steps on a computer to send the new data string to the communication network from the device output.
[0032]
According to the program of the present invention, the invention can be provided through download / installation from an information recording medium (such as package software) or a communication network. Therefore, the present invention can be easily implemented by microcomputers mounted on various devices, and the versatility is improved.
[0033]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. The configuration and signal processing in this description are schematic descriptions to the extent that the present invention can be understood. In other words, the present invention is not limited to the following embodiments, and various modifications and applications based on the description of the claims can be made.
[0034]
(Basic Operation of Configuration and Main Part of First Embodiment)
FIG. 1 is a block diagram illustrating a configuration example of a first embodiment of a data transmission method, a transmission processing device, and a program according to the present invention.
[0035]
Referring to FIG. 1, the data transmission processing apparatus 1 receives input packet sequences D1 and D2 (D1: high transmission priority, D2: low transmission priority) and outputs a high transmission priority packet sequence P_H, And the low transmission priority packet sequence P_LThe transmission priority determining unit 11 (corresponding to the transmission priority determining means in the present invention (claims)) that outputs the transmission priority.
[0036]
Further, the data transmission processing device 1 shown in FIG._HStorage and output section 12 for storing and sequentially outputting (FIFO: (First In First Out)) and the low transmission priority packet sequence P from the transmission priority determination section 11._LAnd a packet accumulation output unit (FIFO) 13 for accumulating and sequentially outputting (FIFO).
[0037]
Further, the data transmission processing device 1 shown in FIG._HAnd low transmission priority packet sequence P_LThe packet header processing unit 14 outputs the header information detected from the header area described in detail below, and transmission control information D6 such as a transmission request and transmission end obtained from the set SLA information. And the transmission control information D6 from the packet header processing unit 14 and the low transmission priority packet sequence P from the packet accumulation output unit 13._L, A packet header creating unit 15 that outputs a divided low transmission priority packet sequence D8 or an undivided low transmission priority packet sequence D8a, and the low transmission priority packet sequences D8, D8a from the packet header generation unit 15. And a packet accumulation output unit 16 for accumulating and sequentially outputting (FIFO).
[0038]
Further, the data transmission processing device 1 shown in FIG. 1 controls the output based on the high transmission priority packet sequence D7 from the packet storage output unit 12 and the low transmission priority packet sequences D8, D8a from the packet storage output unit 16. And an output control unit 17 for transmitting an output packet sequence D9 generated by this output control, in which the low transmission priority packet sequences D8 and D8a are arranged in the high transmission priority packet sequence D7, to a communication network (not shown). (Corresponding to the new data string transmitting means in the present invention (claims)).
[0039]
The packet storage / output units 12, 13, 16 and the packet header processing unit 14 and the packet header creation unit 15 are provided with a non-data section determination unit and a new data string generation unit, a determination processing unit, an arrangement processing unit, Corresponds to the generation processing unit.
[0040]
FIG. 2 is a block diagram showing a specific configuration example of a main part of the data transmission processing device shown in FIG.
[0041]
The specific configuration example of the main part is applied to the packet header processing unit 14 and the packet header creation unit 15 in this embodiment.
[0042]
Referring to FIG. 2, a specific configuration example of this main part is an input / output (I / O) that processes input / output of data between the MPU 21 that executes the calculation and control here and an external device (not shown). (I / O) circuit 25.
[0043]
The MPU 21 has a ROM storing a “program corresponding to the present invention” and other programs by downloading / installing from a CD-ROM or a communication network, a working RAM, and a CPU for performing calculations for executing the program. ing.
[0044]
In this type of configuration, an auxiliary storage device (for example, a hard disk device (HDD), a DMA transfer (Direct Memory Access Transfer) unit, and an input device (keyboard, coordinate input device), etc. are provided. And the description is omitted.
[0045]
(Overall operation of the first embodiment)
FIG. 3 is a diagram for explaining an example of an input packet sequence in the first embodiment, and FIG. 4 is a timing chart for explaining an example of packet forward processing (packet division processing) in the first embodiment. is there. FIG. 5 is a flowchart of an example of packet division processing in the first embodiment, and FIG. 6 is a flowchart of an example of packet output control in the first embodiment.
[0046]
Hereinafter, the overall operations (1) to (8) of the first embodiment will be described with reference to FIGS.
[0047]
(1) A packet (for example, an IP packet) includes a header and a payload data area in a data format. Is stored in
[0048]
Depending on the data in this header area and the set SLA data “lowest transmission priority, transmission rate, packet interval, loss (discard) rate, etc.”, output when a plurality of packets arrive (input) simultaneously Execute control.
[0049]
In the SLA, as data in the header area, transmission priority of transmission (transmission) is different (IETF: Internet Engineering Task Force).
-Highest priority transmission order EF (Expedited Forwarding)
・ AF (Assured Forwarding) 1-4 class
-BE without QoS compensation (Best Effort Forwarding)
Are well known.
[0050]
(2) Here, the transmission band (transmission speed / transmission rate) of a communication network (not shown) on the output side of the data transmission processing device 1 (FIG. 1) is set to “R”.
[0051]
The data transmission processing device 1 receives a packet sequence of long and short data at the same time. The packet sequence of this long and short data amount is as follows: (a) the packet length is short, and the interval between packets is "T_HiInput packet sequence D1 (high transmission priority packet sequence P_H), And (b) the packet length is long and the interval between packets is_HiInput packet sequence D2 (low transmission priority packet sequence P_L).
[0052]
This input packet sequence D1 (high transmission priority packet sequence P_H) And the input packet sequence D2 (low transmission priority packet sequence P_L) Are simultaneously input to the data transmission processing apparatus, the processing described in the following (3) to (8) "high transmission priority packet sequence P_HLow priority packet sequence P_LEach packet is arranged (inserted) or divided and arranged and transmitted.
[0053]
(3) In FIG. 1, the transmission priority judging unit 11 supplies two input packet sequences D1 and D2 (high transmission priority packet sequence P_H,Low transmission priority packet sequence P_LIs entered.
[0054]
The transmission priority determining unit 11 determines the transmission priority of the input packet sequence D1, D2 from the specified SLA, and determines the high transmission priority packet sequence P_H(D3) is output to the packet header processing unit 14, and is also output to the packet accumulation output unit 12, where it is accumulated.
[0055]
Further, the transmission priority determining unit 11 determines the transmission priority of the input packet sequence D1 or D2 based on the SLA rules, and determines the low transmission priority packet sequence P_L(D4) is output to the packet header processing unit 14 and is also output to the packet accumulation output unit 13, where it is accumulated.
[0056]
(4) In the packet header processing unit 14, the high transmission priority packet sequence P_H(D3) and low transmission priority packet sequence P_LThe transmission request (transmission start, for example, SOH: Start of Heading) stored in the field of the header area of (D4) is detected, and the transmission end (for example, EOT: End of Transmission, end of division block ETB: End Transmission Block) is detected.
[0057]
The header information detected from this header area and the transmission control information D6 such as the transmission request and the transmission end obtained from the set SLA information are output to the packet header creating unit 15.
[0058]
3 and 4, the operation is defined as follows, and the operation will be described below.
[0059]
Input packet sequence D1 (high transmission priority packet sequence P_H) Is the packet length = L_HiAnd packet interval = T_HIiIt is. Further, the input packet sequence D2 (low transmission priority packet sequence P_L) Is the packet length = L_LiAnd packet interval = T_LIiIt is. Further, according to the SLA regulations, the high transmission priority packet sequence P_HIs the maximum allowable interval T between_max(T_max> T_HI).
[0060]
The output side is the transmission band R, and the high transmission priority packet sequence P_HIs the header length = H_HIt is. In addition, the low transmission priority packet sequence P_LIs the header length = H_LIt is.
[0061]
(5) In FIG._L/ R ≦ T_HI, That is, the high transmission priority packet sequence P_HIs a low transmission priority packet sequence P_LIs longer than the respective packet lengths, the high transmission priority packet sequence P_HLow priority packet sequence P_LTransmission (communication) in which each packet is arranged (inserted) is performed.
[0062]
In FIG. 4, L_L/ R> T_HIThat is, the high transmission priority packet sequence P_HIs a low transmission priority packet sequence P_LIf the packet length is shorter than the packet length of_HLow priority packet sequence P_LCannot be transmitted as it is. In this case, the following processing is performed.
[0063]
Also, L_L/ R> T_HIThat is, the high transmission priority packet sequence P_HIs a low transmission priority packet sequence P_LIs shorter than the header length of the high transmission priority packet sequence P_HLow priority packet sequence P_LTransmission with each packet placed is not possible. In this case, for example, a packet discarding process through the packet header creating unit 15 or a process of putting the packet into a queue is performed.
[0064]
(6) L_L/ R <T_HIThat is, the high transmission priority packet sequence P_HIs a low transmission priority packet sequence P_LIs longer than the header length of the high transmission priority packet sequence P_HLow priority packet sequence P_LTransmission is performed by distributing each packet.
[0065]
To each of the divided packets, data relating to a header that unifiedly indicates the same input data string is added. The data regarding the headers that are unified are first divided to create a common part of the header of the newly generated packet. In addition, a part that depends on the new divided packet is created individually. The common part and the individual part depending on the new packet are connected, for example, on the receiving side to generate a packet header, and the low transmission priority packet sequence P before splitting is generated._LReassemble.
[0066]
The low-priority packet sequence P in the receiving system (not shown)_LIs reassembled.
[0067]
The operations of the processes (5) and (6) will be described as the processing procedure (flow processing / FIGS. 5 and 6) of the packet header creation unit 15 and the output control unit 17.
[0068]
Referring to FIG. 5, first, based on the transmission control information D6 from the packet header processing unit 14 described above (step S1), the packet header creating unit 15 selects the high transmission priority packet sequence P_HLow transmission priority packet sequence P between each packet_LIt is determined whether or not transmission in which each packet is arranged is possible (step S2).
[0069]
If the transmission in which the packets are arranged is possible in the process of step S2 (Yes), the process proceeds to step S8, where the packet accumulation / output unit 16 sets the low transmission priority packet sequence P_LIs stored. Thereafter, in the output control unit 17, the high transmission priority packet sequence P from the packet accumulation output unit 12 is output._H, The low transmission priority packet sequence P from the packet accumulation output unit 16_LEach packet is arranged without being divided and its output packet sequence D9 is transmitted (see FIG. 6 below).
[0070]
In the process of step S2, the low transmission priority packet sequence P_LIf the transmission in which is arranged is impossible (No), the process proceeds to step S3, and thereafter, the following processes (a) and (b) are executed.
[0071]
(A) High transmission priority packet sequence P_HIs a low transmission priority packet sequence P_LEach packet is longer than the header length and has a high transmission priority packet sequence P_H, A low transmission priority packet sequence P_LThe transmission in which the respective packets are arranged cannot be performed (see the description of the packet discarding process in (5) above) (step S3: No).
[0072]
(B) High transmission priority packet sequence P_HIs the packet interval T_HIiIf it is shorter (step S4: No), in this example, the next packet (input packet sequence D1, D2) is not input until the current packet transmission process ends by the timing process shown in FIG. In this case, the high transmission priority packet sequence P_HMaximum allowable packet interval T_max, A low transmission priority packet sequence P_LPackets of length L_i= (R × T_max-1) (steps S5, S6, S7).
[0073]
This length L_i= (R × T_maxAccording to -1), the packet header creating unit 15 sends the low transmission priority packet sequence P_LIs read, and a low transmission priority packet sequence D8 divided as described above is created (step S5), output to the packet accumulation output unit 16, and stored therein (step S8).
[0074]
(C) The processing is performed as described above, and the processing in the packet header creation unit 15 for the input packet sequences D1 and D2 ends.
[0075]
(8) Next, referring to FIG. 6, the packets of each of the divided low-transmission-priority packet sequences D8 are output from the packet accumulation output unit 16 to the output control unit 17 (step S10).
[0076]
In this case, the output control unit 17 receives alternately the divided packets of the low transmission priority packet sequence D8 and the packets of the high transmission priority packet sequence D7 from the data storage output unit 12. That is, the respective packets of the low transmission priority packet sequence D8 divided between the respective packets of the high transmission priority packet sequence D7 are arranged (inserted).
[0077]
Note that the low transmission priority packet sequence P_LIs a high transmission priority packet sequence P_HWhen the transmission (transmission) is started earlier than the input and the transmission (transmission) is started earlier, the low transmission priority packet sequence P_LThe control for terminating the transmission is executed by, for example, a higher-level control system (not shown) of the data transmission processing device 1. Thereafter, as in the above (3) to (8), the dividing process is executed.
[0078]
(Advantages of the first embodiment)
As described above, in the first embodiment, two types of input packet sequence D1 (high transmission priority) and input packet sequence D2 (low transmission priority) having high and low transmission priorities are guaranteed in the high transmission priority. And then reliably transmit. Also, transmission data of low transmission priority can be transmitted efficiently without any special delay. As a result, it is possible to improve the utilization efficiency of the transmission band in the communication network.
[0079]
In this case, for example, the packet transmission priority control in the traffic management control for avoiding congestion in the packet communication network is performed by a relatively simple system configuration, that is, the data transmission processing device 1 shown in FIG. This can be performed by arranging only at the device output side to the network (for example, a routing device or a network access device).
[0080]
(Configuration of Second Embodiment and Basic Operation of Each Unit)
FIG. 7 is a block diagram illustrating a configuration example of a three-input data transmission processing device according to the second embodiment.
[0081]
Referring to FIG. 7, the three-input data transmission processing device 1A according to the second embodiment adds a new medium transmission priority packet sequence to the highest priority transmission priority packet sequence to the data transmission processing device 1 shown in FIG. It has an additional component part (within a dotted frame in FIG. 7) for arranging between packets.
[0082]
FIG. 7 shows a function similar to that of the data transmission processing apparatus 1 shown in FIG. 1, and the input packet sequence D1 (highest priority transmission order / high transmission priority order packet sequence P_H) And an input packet sequence D2 (low transmission priority / low transmission priority packet sequence P_L) In the same way as in the first embodiment, a packet accumulation output unit 12, 13b, 16b, a packet header processing unit 14a that outputs transmission control information D6a, and a packet header creation unit. 15b and an output control unit 17a.
[0083]
Further, as a configuration for performing the operation unique to the second embodiment, the three-input data transmission processing device 1A includes the medium transmission priority packet train P from the transmission priority determination unit 11A._M(D4a) is stored and sequentially output (FIFO), and a medium transmission priority packet sequence P from the packet storage and output unit 13a is provided._M(D4a) Creating a packet header that outputs a medium transmission priority packet sequence D8b with a header for each divided packet for arranging each packet by dividing it into packets of an input packet sequence D1 (high transmission priority). It has a portion 15a.
[0084]
Further, the three-input data transmission processing device 1A attaches a header to each divided packet from the packet header creating unit 15a for dividing and arranging the packets in the input packet sequence D1 (high transmission priority). And a packet accumulation output section 16a for accumulating and sequentially outputting (FIFO) the intermediate transmission priority packet sequence D8b.
[0085]
(Overall operation of the second embodiment)
FIG. 8 is a timing chart for explaining an example of packet forward processing (packet division processing) in the second embodiment.
[0086]
Referring to FIGS. 7 and 8, the three-input data transmission processing device 1A of the second embodiment functions in the same manner as the data transmission processing device 1 shown in FIG. ) And the input packet sequence D2b (low transmission priority) are basically processed by the configuration from the transmission priority determination unit 11A to the output control unit 17a, as in the first embodiment of FIG. That is, as shown in FIG. 7, the divided packets of the input packet sequence D2b (low transmission priority) are arranged between the packets of the input packet sequence D1 (highest priority transmission order).
[0087]
Further, in the second embodiment, the input packet sequence D2a (medium) is connected between the packets of the input packet sequence D1 (highest priority transmission order) so as to be connected to the divided packet of the input packet sequence D2b (low transmission priority order). (Transmission priority).
[0088]
The arrangement of the input packet sequence D2a (medium transmission priority) to the input packet sequence D2b (low transmission priority) is performed by processing for matching the timing on the time axis.
[0089]
This timing matching is performed by the connection information Dc with the packet header creation units 15a and 15b, and the low transmission priority packet sequence P_L(D4b) and medium transmission priority packet sequence P_M(D4a), the divided packets are concatenated to form a high transmission priority packet sequence P_HA process (control) of delaying the divided packet is executed so as to be arranged between the packets of (D3).
[0090]
By performing the above processing, the output packet sequence D9a is output from the output control unit 17a to a communication network (not shown).
[0091]
(Advantages of the second embodiment)
In the second embodiment, the input packet sequence D1, D2a, D2b (highest priority, medium transmission priority, low transmission priority) of three or more types of transmission priorities including high, medium, and low is determined according to the first embodiment. With a relatively simple system configuration similar to the form, the transmission priority of the highest priority is guaranteed and transmitted reliably, and transmission data of medium and low transmission priorities can be efficiently performed without special delay. Transmission becomes possible, and the utilization efficiency of the transmission band in the communication network can be improved.
[0092]
(Application Example of Embodiment)
FIG. 9 is a communication network diagram showing a main part of an application configuration example of the data transmission processing devices 1 and 1A in the first and second embodiments.
[0093]
In the configuration of the main part of the application configuration example of the first and second embodiments, the data transmission processing devices 1 and 1A of the first and second embodiments are a routing device, a network access device (for example, a gateway (GW)). Processing device).
[0094]
Referring to FIG. 9, in the main part of this application configuration example, the accommodation side of the communication line network 30 in the routing devices (routers) 32, 34, 36 to which the communication terminals 33, 35, 37 are connected (the present invention (claim) (Corresponding to the output side in item (1)).
[0095]
Note that the data transmission processing devices 1 and 1A according to the first and second embodiments can be arranged in the GW processing device 31 as well as the routing devices (routers) 32-36. The operational effects (advantages) are the same as above.
[0096]
(Advantages of the application example of the embodiment)
The data transmission processing devices 1 and 1A do not need to be mounted on each node in the communication line network, but are mounted on nodes for which the use efficiency of the transmission band is to be improved. Also, when transmitting a sequence of packets having different transmission priorities, the packet sequence is implemented in nodes sharing the transmission band.
[0097]
(Modification of Embodiment)
In the above-described first and second embodiments, the packet interval of each of the input packet sequences D1 (highest priority transmission order) is fixed (specified by IETF or the like). In particular, it is also possible to adopt a configuration in which the input packet sequences D2a and D2b (medium, low transmission priority) are arranged so as to be widened so as not to give a transmission delay. In this case, the configuration can be easily realized by performing processing for matching the delay and the read timing of the FIFO.
[0098]
In the second embodiment, the configuration example in which three input packet sequences D1, D2a, and D2b are input has been described. However, a process of arranging four or more input packet sequences is also added to FIG. This can be realized by further connecting the configuration.
[0099]
Such modified configurations are within the scope of design matters for those skilled in the art, and are all included in the present invention.
[0100]
【The invention's effect】
As is apparent from the above description, according to the method for transmitting data having different transmission priorities, the transmission processing apparatus, and the program according to the present invention, transmission data of a plurality of types of transmission priorities can be realized by a relatively simple system configuration. Can be reliably transmitted by guaranteeing its highest priority transmission priority, and transmission data of medium and low transmission priorities can be transmitted efficiently without any special delay.
[0101]
As a result, it is possible to improve the utilization efficiency of the transmission band in the communication network.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration example of a first embodiment of a method for transmitting data having different transmission priorities, a transmission processing device thereof, and a program according to the present invention.
FIG. 2 is a block diagram showing a specific configuration example of a main part of the data transmission processing device shown in FIG.
FIG. 3 is a diagram for explaining an example of an input packet sequence in the first embodiment.
FIG. 4 is a timing chart for explaining an example of packet division processing in the first embodiment.
FIG. 5 is a flowchart illustrating an example of a packet division process according to the first embodiment.
FIG. 6 is a flowchart illustrating an example of packet output control according to the first embodiment.
FIG. 7 is a block diagram illustrating a configuration example of a three-input data transmission processing device according to a second embodiment.
FIG. 8 is a timing chart for explaining an example of packet division processing in the second embodiment.
FIG. 9 is a communication network diagram to which the data transmission processing device according to the first and second embodiments is applied.
[Explanation of symbols]
1, 1A ... data transmission processing device
11, 11A: Transmission priority determination unit
12, 13, 13a, 13b, 16, 16a, 16b... Packet storage / output unit (FIFO)
14, 14a: Packet header processing unit
15, 15a, 15b ... packet header creation unit
17, 17a ... output control unit
32, 34, 36 ... routing device (router)
33, 35, 37 ... communication terminals
D1, D2, D2a, D2b ... input packet sequence
D6, D6a ... transmission control information
D7: High transmission priority (highest priority) packet sequence
D8, D8a: low transmission priority packet sequence
D8b: Medium transmission priority packet sequence
D9, D9a ... output packet sequence
P_H(D3): High transmission priority (highest priority transmission) packet sequence
P_M(D4a): Medium transmission priority packet sequence
P_L(D4, D4b) ... low transmission priority packet sequence

Claims (12)

In each input data sequence of a plurality of transmission priorities, a step of determining a non-data section of the input data sequence of the highest priority transmission order,
In the determined no-data section, each data in the input data sequence having the lower transmission priority than the highest transmission priority is arranged, and a new transmission priority including the highest priority transmission order and the lower transmission priority is guaranteed. Generating a data sequence;
Transmitting the new data sequence to the communication network from the device output side;
A method for transmitting data having different transmission priorities. In the step of generating the new data sequence,
It is determined whether or not each data in the low transmission priority input data sequence can be arranged in the non-data section, and then, in this determination, when each data in the low transmission priority input data sequence can be arranged. Then, each data in the input data sequence of the low transmission priority is arranged in the non-data section of the input data sequence of the highest transmission priority, and then the new data composed of the highest priority transmission order and the low transmission priority by this arrangement is arranged. Generate a simple data string,
2. The method according to claim 1, wherein the data has different transmission priorities. In the step of generating the new data sequence,
It is determined whether or not each data in the low transmission priority input data sequence can be arranged in the non-data section, and then, when each data in the low transmission priority input data sequence cannot be arranged in this judgment. Then, each data in the input data sequence of the lower transmission priority is divided and arranged, and then a new data sequence consisting of the highest priority transmission order by this arrangement and a lower transmission priority than the highest priority transmission order is generated. Generate,
2. The method according to claim 1, wherein the data has different transmission priorities. When dividing and arranging each data in the input data sequence of the low transmission priority,
4. The method according to claim 3, wherein each data in one type or a plurality of types of low-priority transmission input data strings is divided and arranged. The data relating to the header, which uniformly indicates the same input data string, is added to each of the data of the one kind or the plurality of kinds of input data strings of the low transmission priority which are divided and arranged. The method for transmitting data having different transmission priorities according to claim 4, wherein the transmission is performed by arranging the data. The input data sequence is
2. The method according to claim 1, wherein the packet sequence has a data structure including a header area and a payload data area of a variable length or a fixed length. In a data transmission processing device that transmits data with a plurality of types of transmission priorities,
Transmission priority determining means for determining the priority in each input data sequence of a plurality of types of transmission priority,
No data section determination means for determining a no data section of the input data sequence of the highest priority transmission order in the transmission priority determination means,
In the no-data section determined by the no-data section determining means, the respective data in the input data sequence having the lower transmission priority than the highest priority transmission order are arranged, and the transmission priority including the highest priority transmission order and the lower transmission priority is arranged. A new data string generating means for generating a new data string whose order is guaranteed,
New data string transmitting means for transmitting a new data string by the new data string generating means to the communication network from the output side of the transmission processing device to the communication network;
A data transmission processing device comprising: A determination processing unit that determines whether each data of the input data sequence of the low transmission priority can be arranged in the non-data section determined by the non-data section determination unit,
When each data of the input data sequence of the low transmission priority can be arranged by the determination by the determination processing unit, each data in the input data sequence of the low transmission priority is deleted from the input data sequence of the highest transmission priority. An arrangement processing unit arranged in the data section;
A generation processing unit that generates a new data string including the highest priority transmission order and the low transmission priority in the arrangement by the arrangement processing unit;
The data transmission processing device according to claim 7, comprising: A determination processing unit that determines whether each data of the input data sequence of the low transmission priority can be arranged in the non-data section determined by the non-data section determination unit,
When each data of the input data sequence of the low transmission priority cannot be arranged by the judgment in the judgment processing unit, an arrangement processing unit for dividing and arranging each of the input data sequences of the low transmission priority,
A generation processing unit that generates a new data string including the highest priority transmission order and the lower transmission priority than the highest priority transmission order by the arrangement in the arrangement processing unit,
The data transmission processing device according to claim 7, comprising: 8. The data transmission processing device according to claim 7, wherein the data transmission processing device is arranged on an output side connected to a communication network. In each input data sequence of the plurality of transmission priorities, a step of determining a non-data section of the input data sequence of the highest priority transmission order,
Determining whether or not each data of the input data sequence of the low transmission priority can be arranged in the determined no-data section;
In this determination, when each data of the input data sequence of the low transmission priority can be arranged, in the non-data section of the input data sequence of the highest transmission priority, the same as each data of the input data sequence of the low transmission priority. Adding and arranging data relating to a header that uniformly indicates that the input data string is
Generating a new data sequence consisting of the highest priority transmission order and the low transmission priority by this arrangement;
Transmitting the new data sequence to the communication network from the device output side;
A program for causing a computer to execute. In each input data sequence of the plurality of transmission priorities, a step of determining a non-data section of the input data sequence of the highest priority transmission order,
Determining whether or not each data of the input data sequence of the low transmission priority can be arranged in the determined no-data section;
In this determination, when the respective data of the input data sequence of the low transmission priority cannot be arranged, one type or a plurality of types of the low transmission priority divided into the non-data section of the input data sequence of the highest priority transmission order. A step of adding and arranging data relating to a header that uniformly indicates that the data is the same input data string to each data of the input data string;
Generating a new data sequence consisting of the highest priority transmission order by this arrangement and a lower transmission priority than the highest priority transmission order;
Transmitting the new data sequence to the communication network from the device output side;
A program for causing a computer to execute.

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