JP3511918B2 - Priority transfer control device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a priority transfer control device for guaranteeing a maximum allowable delay time of packet transfer from end to end in a network.

In recent years, applications that support multimedia such as graphics, still images, voices, and moving images that operate on personal computers have become widespread. When such an application transmits / receives information via a network, there is a severe demand for a delay time of a packet for transferring information such as voice and video. As described above, it is desired to provide a transmission system in which priority transfer control of packets is performed within the maximum allowable delay time according to a request from an application or the like.

[0003]

2. Description of the Related Art In recent years, such quality of service (Qualit
y of Service) Assurance methods are being actively studied. A typical method is RSVP (resource ReSerVation
On all the relay devices that pass through the transfer path for each end-to-end packet flow (hereinafter referred to as a flow, which includes a set of flows) by a protocol such as Reserve bandwidth at WFQ (Weighted Fair Queuing), WRR (Weighted Round)
Robin) and other packet scheduling techniques to guarantee a certain preset bandwidth,
A method of performing flow control is known. In such a method, it is necessary to provide a mechanism for guaranteeing the bandwidth reserved by all the relay devices on the transmission path through which the packet passes.

However, if there is a relay device that does not have such a mechanism on the transmission path, there remains a problem that the following packet transfer delay time cannot be solved. The problem will be described with reference to FIG.

FIG. 7 is a diagram for explaining the occurrence of packet transfer delay. In the figure, 10, 20, and 30 are relay devices. Among them, the relay device 10 is a device that does not have a bandwidth guarantee mechanism, and reference numerals 1, 2, 3, and 4 represent flows. In the relay device 10, when the packets of the flow 1 are burst-input to the relay device 10 and output to another relay device (not shown), the transfer output of the packet of the flow 2 is delayed and the relay device 30 The input status is shown. On the other hand, in the relay device 20, the packet of the flow 3 is input, transferred, and output, but since the absolute number of packets input to the relay device 20 is small, the flow is flowed.
The packet No. 3 is input to the relay device 30 with a small delay time.

Therefore, the relay device 30 guarantees the packet transfer amount of the input flow per unit time, but cannot perform the priority control of the transfer output according to the delay time of the input packet. was there.

[0007]

That is, according to the current method, since the information regarding the maximum allowable delay time is not set in each packet for the flow 2 of the delayed packet from the relay device 10, the delayed packet is relayed in each relay. The device cannot prioritize transfer control. In other words, there is a problem that the delay of the packet delayed beyond the maximum allowable delay time cannot be recovered.

[0008]

Means for Solving the Problems Means for solving the above problems will be described below.

According to a first aspect of the present invention, in a priority transfer control device that relays a packet received on a network to a desired destination, when a received setup packet is relayed, a calculated start-point relay required When the time is held in the own device corresponding to the flow of the setup packet and the setup packet is transmitted, and the received backward setup packet is relayed, the time is held in the own device corresponding to the flow. The expected start relay required time is calculated from the product of the start relay required time and the time allocation coefficient set in the reverse setup packet, and the maximum allowable delay time set in the reverse setup packet and the start relay required time are obtained. The difference from the expected value is obtained as the relay termination required time expected value, and the relay termination required time period is sent to the own device in accordance with the flow. When the backward setup packet is transmitted while holding the wait value, the time allocation coefficient, and the maximum allowable delay time, and the received data packet is relayed, the delayed data packet is detected from the received data packet, The priority transfer control device is characterized in that the detected delay data packet is preferentially transmitted, and data packets other than the delay data packet are normally transmitted.

[0010] In the invention described in claim 2, wherein the relaying of data packets, the received priority transfer control with and transferring preferentially large delay data packet delay time from the delay data packet It is a device.

In the invention according to claim 3 , the start end relay required time expected value is, when the setup packet is relayed, a current reference time of the own device and a transmission reference time set in the setup packet. The priority transfer control is characterized in that the start relay required time is obtained from the difference between the two, and the start relay required time expected value is obtained by the product of the start relay required time and the time distribution coefficient held corresponding to the flow. apparatus.

In the invention according to claim 4 , the relay termination required time expected value is a combination of the maximum allowable delay time held in the own device corresponding to the flow and the start end relay required time expected value. The priority transfer control device is characterized by being obtained from the difference.

According to a fifth aspect of the present invention, a first relay termination required is calculated from a difference between the maximum allowable delay time previously held in the own device corresponding to the flow and the expected start relay required time. A time expected value is obtained, and the data packet is delayed when the first expected value of relay termination required time is smaller than the expected value of second relay termination required time previously held in the device in association with the flow. A priority transfer control device comprising a transfer control means for performing priority transfer control as a data packet, and normally performing transfer control when it is not the delayed data packet.

According to a sixth aspect of the present invention, the start relay required time is obtained from the difference between the current reference time of the own device and the transmission reference time set in the received data packet, and the start relay required time is set to the start relay required time. The first expected start relay time required value is obtained from the product of the time distribution coefficient held in the device itself or the time distribution coefficient set in the data packet corresponding to the flow of the data packet, and the first starting relay If the expected time required value is larger than the second expected start relay required time expected value held in the own device corresponding to the flow of the data packet, it is detected as the delayed data packet, and is subjected to priority transfer control. It is a characteristic priority transfer control device.

According to a seventh aspect of the present invention, a start relay time required is calculated from a difference between a current reference time of the device itself and a transmission reference time set in the received data packet, and the start relay required time is set to the start relay time. The expected start relay time required value is obtained from the product of the time distribution coefficient held in the device itself or the time distribution coefficient set in the data packet corresponding to the flow of the data packet, and is sent out in the data packet. The relay expected transmission reference time is calculated from the sum of the reference time and the expected value of the start relay time, and if the relay expected transmission reference time is ahead of the current reference time, the data packet is preferentially transferred as the delay data packet. It is a priority transfer control device characterized by controlling.

According to an eighth aspect of the invention, a start relay required time is obtained from a difference between a current reference time of the own device and a transmission reference time set in the received data packet, and the data is set to the start relay required time. The expected start relay required time is obtained from the product of the time distribution coefficient held in the device itself or the time distribution coefficient set in the data packet corresponding to the flow of the packet, and the arrival criterion set in the data packet An expected value of relay end required time is obtained from the difference between the time identifier and the expected value of the relay end required time, and when the expected value of relay end required time is ahead of the current reference time, the data packet is regarded as the delayed data packet. A priority transfer control device characterized by performing priority transfer control.

According to a ninth aspect of the present invention, the time-out time of either the sum of the transmission reference time set in the data packet and the time-out time or the time-out time set in the data packet is calculated, and the time-out time is calculated. The priority transfer control device is characterized in that when the time is later than the current reference time, the data packet is discarded.

According to a tenth aspect of the present invention, in a priority transfer control device that receives a packet from a desired source on a network, when a data packet addressed to itself is received, the data packet is sent to an upper layer. Then, when the setup packet addressed to the own device is received, the start end termination required time is obtained from the difference between the current reference time of the own device and the transmission reference time set in the setup packet,
Priority transfer control characterized by obtaining a time allocation coefficient by dividing the specified maximum allowable delay time by the time required for the start terminal and ending, generating a reverse direction setup packet including the time allocation coefficient, and returning the packet to the starting terminal device. It is a device.

According to an eleventh aspect of the present invention, there is provided a priority transfer control device characterized in that, in the return of the reverse direction setup packet, the reverse direction setup packet includes the maximum allowable delay time.

According to a twelfth aspect of the present invention, a start end termination required time is obtained from a difference between a current reference time and a transmission reference time set in the setup packet, and the reverse setup packet includes the start end termination required time. This is a priority transfer control device characterized by the above.

According to a thirteenth aspect of the present invention, in a priority transfer control device for performing priority transfer control of packets on a network, when a transfer packet is transmitted, it corresponds to a transmission reference time of the transfer packet and a flow of the transfer packet. When a transfer packet is relayed by setting the time distribution coefficient held in the device in advance, the start point is determined from the difference between the current reference time and the transmission reference time set in the received transfer packet. The relay required time is calculated, the first expected start relay required time is obtained from the product of the start relay required time and the time distribution coefficient, and the second expected start relay required time is already stored in the own device corresponding to the flow. If the second expected start relay required time is smaller, the transfer packet is preferentially transmitted, and if not, the transfer packet is normally transmitted. , When receiving a transfer packet, calculates the start-end termination time from the difference between the current reference time and the transmission reference time set in the transfer packet, and sets the start-end termination required time in the generated reverse transfer packet. Then, when the backward transfer packet is sent back to the transmission source of the backward transfer packet and the backward transfer packet is relayed, the received backward transfer packet is sent toward the starting end device, and when the backward transfer packet is received. , The maximum permissible delay time is divided by the required time at the start and end set in the reverse transfer packet to obtain a time distribution coefficient, and the time distribution coefficient is associated with a flow opposite to the flow of the reverse transfer packet. It is a priority transfer control device characterized by being held in its own device.

According to a fourteenth aspect of the invention, when relaying the transfer packet, the start relay required time is obtained from the difference between the current reference time and the transmission reference time set in the transfer packet, and the start relay required time is calculated. Is a priority transfer control device characterized by obtaining an average value of the previous required start-point relay required time and calculating an expected value of the start-end relay required time based on the average value.

The sending reference time, reference time, arrival reference time identifier and timeout time used in this specification are
It may be standard time in Japan or Greenwich mean time. Alternatively, it may be a relative time, such as a stopwatch, whose transmission reference time is 0:00.

Note that the configurations of the present invention can be combined with each other as much as possible.

The above-mentioned method is provided as means for solving the above-mentioned problems.

[0026]

BEST MODE FOR CARRYING OUT THE INVENTION <Basic Principle of the Invention> First, a basic principle that helps to understand an embodiment of the present invention will be described below. FIG. 1 is a diagram for explaining the basic principle of the present invention.
Reference numeral 40 is a starter device that provides a sending function for sending out a packet, 50 is a relay device that provides a function for relaying the packet, and 60 is a terminating device that provides a function for receiving the packet. The starting point device 40, each relay device 50, and the terminating device 60 are all the same device, but are described separately for the starting end device 40, the relay device 50, and the terminating device 60 depending on the function used. It is assumed that the clocks of the start point device 40, the one or more relay devices 50, and the end device 60 have the same time. In order to make the times coincide with each other, it is possible to keep the time of each device the same so that there is no problem by using NTP (Network Time Protocol) which is a protocol for providing the exact same time.

In the figure, the maximum allowable delay time is set by an application program or the like, and the start end device 40
The packet sent from the device is subjected to priority transfer control by each relay device so as to be within the maximum allowable delay time. The expected start-time relay required time indicates an expected value of the required time from the start-end device to the relay device when the transfer from the start-end device to the end device is performed with the maximum allowable delay time. Similarly, the relay termination required time expected value also indicates the expected value of the required time from the relay device to the terminating device when transferred with the maximum allowable delay time. On the other hand, the start-end relay required time indicates the required time from the start-end device to the relay device that is actually measured by the setup packet, and the relay-end required time is also the required time measured from actually traveling from the relay device to the end device. Indicates.

In the figure, each device has a transfer control means 21 for performing priority transfer control of packets, and an expected value setting for setting information necessary for performing priority transfer control of packets (for example, expected value of relay termination required time). It is shown that the means 22 and the upper layer 23 such as a communication application are provided. The upper layer 23 is an application or the like, and particularly for an application that handles voice, images, etc., the demand for the packet transfer delay time is severe. Therefore, such an application is typically used with the starter device 40.
Requests a small value for the maximum allowable delay time of a packet from when the packet reaches the terminating device 60 via the relay device 50. On the other hand, in applications such as electronic mail that do not require real-time processing, the demand for delay time in packet transfer is not strict. Thus, it can be said that there are various requests for the packet delay time in the upper layer 23. Here, the upper limit layer 23 sets the maximum allowable delay time with respect to the delay time of packet transfer. However, if the application omits the setting of the maximum allowable delay time, or if the upper layer 23
A method of identifying the application may be considered, and the expected value setting means 22 may specify or set the maximum allowable delay time.

According to the present invention, a setup packet is actually transferred from the start end device 40 to each end device 60 via each relay device 50 for each flow, and the start end termination time from the start end device 40 to the end device 60 is set. The time distribution coefficient, the start relay required time expected value, and the relay terminated required time expected value, which are obtained by actually measuring and considering the maximum allowable delay time based on the start end terminating time, are set for each relay device 50 and for each flow. Set to. This is called an expected value setting phase.

Next, the relay device 5 from the starting end device 40
The start relay required time is actually measured by passing the setup packet through 0, and the start relay obtained by the product of the start relay required time and the time distribution coefficient (value obtained by dividing the maximum allowable delay time by the start end termination time) The expected time required value is held for each relay device 50 and corresponding to each flow, and at the time of transferring the data packet, the start point is set to the current reference time and the transmission reference time set in the data packet. Delayed data packet by comparing the expected relay transmission time with the expected relay required time (if the expected relay transmission time is ahead of the current reference time of the device itself, for example, the expected relay transmission time is Even though it is 18:00:01, the current reference time of the device itself is 18:00.
(Representing a data packet in the case of minutes 00 seconds) is detected, and each delay device 40 prioritizes the delay data packet so that the delay time to the terminating device 60 falls within the maximum allowable delay time as much as possible. Forward. The detection of the delayed data packet includes a method of comparing an expected value of the start relay required time obtained when the setup packet is transferred with an expected value of the start relay required time obtained when the data packet is transferred, and a setup method. There is also a method of comparing the expected value of the relay terminal required time obtained when the packet is transferred with the expected value of the relay terminal required time obtained when the data packet is transferred.

The correction of the delay time of the delayed data packet described above is called the priority transfer control phase. Next, the operations of the expected value setting phase and the priority transfer control phase will be described in detail. <Expected Value Setting Phase> The expected value setting phase performed by the expected value setting means 22 will be described with reference to FIGS. 1 and 2. FIG. 2 is a diagram illustrating a packet flow according to the first embodiment of this invention. The originating device 40 generates the setup packet shown in FIG. 2, sets the sending reference time of the device in the sending reference time 24 field of the setup packet, and sets the timeout identifier or the timeout time from the sending reference time as the timeout identifier 25. Set. Then, the setup packet is sent to the terminating device 60. The setup packet is relayed by one or more relay devices 50 and arrives at the terminating device 60. Upon receipt of the setup packet, each relay device 50 receives the transmission reference time 24 and the timeout identifier 2
5 is extracted, and the expected value setting means 22 outputs the current reference time and the transmission reference time 24 set in the setup packet.
Calculate the difference between and to obtain the start relay time. The transfer control means 2 correlates the required time at the start point relay with the current flow.
Hold at 1.

The terminating device 60 receives the setup packet, calculates the difference between the current reference time of the device itself and the transmission reference time 24 set in the setup packet, and obtains the start end time required. Further, the above-mentioned maximum allowable delay time is divided by the time required for the start end and the end to obtain a time distribution coefficient. Then, a backward setup packet is generated as a response to the setup packet, the maximum allowable delay time is set to the maximum allowable delay time 26, the time allocation coefficient is set to the time allocation coefficient 27, and the packet is returned to the start end device 40. To do. Each relay device 50 is a terminating device 40.
Upon receiving the reverse setup packet from the relay device 50, the relay device 50 can obtain the relay termination required time expected value from the relay device 50 to the termination device 60 by the following procedure.

(1) Receive the reverse setup packet and extract the maximum allowable delay time and the time allocation coefficient.

(2) The reverse flow is obtained from the flow of the reverse setup packet, and the start relay time required for each relay device 50, which is already held in the own device, is extracted.

(3) The starting relay required time is multiplied by the time allocation coefficient to obtain an expected start relay required time. Corresponding to the reverse flow, the start point relay required time expected value is held in the own device. When the data packet is transmitted, if the time distribution coefficient 2A and the transmission reference time and the maximum allowable delay time are set in the arrival reference time identifier 28 in the data packet, the current reference time and the data packet are set. It is also possible to obtain the expected value for the start relay required time by multiplying the difference from the set transmission reference time by the time distribution coefficient.

(4) The expected value of the relay end required time is obtained from the difference between the maximum allowable delay time and the expected value of the start end relay required time. The relay termination required time expected value is held in the own device in association with the reverse flow.

(5) The setup packet and the reverse setup packet are transmitted at predetermined time intervals,
Fluctuations in the delay time in packet transfer are absorbed by calculating the average value with the previous expected value of the relay termination time each time and setting the expected value of the required relay termination time each time.

The maximum allowable delay time set by the upper layer 23 is set in the backward setup packet and transferred to the starting end device 40. However, as described above, the expected value setting means 22 can also set the maximum allowable delay time in the setup packet and send it to the terminating device 60. Further, the setup packet and the reverse setup packet can obtain the same result as a single packet containing no user data or a packet containing user data and information for priority transfer control.

With the above method, the setting of the relay termination required time expected value is completed for each relay device 50, and the first expected value setting phase is completed. This is repeated at regular time intervals. <Priority Transfer Phase> A method of priority transfer control of data packets will be described below.

First, the start-point device 40 sets the arrival reference time to arrive at the end device 60 in each data packet,
It is sent to the terminating device 60. The transmitted data packet is passed through one or more relay devices 50 and the terminating device 6
Reach 0. In each relay device 50, the received data packets are stored on a first-come-first-served basis, and if there is an indication of priority transfer within time, the relay termination from the relay device 50 to the termination device 60 set in the expected value setting phase is performed. It is calculated whether the data packet arrives at the terminating device 60 by the arrival reference time from the expected value of the required time, the current reference time, and the arrival deadline time set in the data packet, and the priority transfer is performed in the following procedure. Determine whether to make it a control target.

(1) In-time priority transfer 2 for data packet
If priority transfer information is set in 9, priority transfer is performed. If it is not set, priority transfer control is not performed.

(2) Extract the flow and arrival reference time of the data packet from the received data packet.

(3) The relay termination required time expected value held corresponding to the flow is extracted.

(4) Subtract the expected value of the relay termination required time from the arrival reference time to obtain the expected relay transmission time.

(5) The current reference time is compared with the relay expected transmission reference time, and when the relay expected transmission reference time is delayed, the data packet is subjected to priority transfer control.

(6) The data packets subjected to the priority transfer control are sorted in descending order using the relay expected transmission reference time as a key, and the packets having the latest expected transmission reference time delayed are sequentially transferred in priority. Thus, the delay time is corrected by preferentially transferring the most delayed data packet, and control is performed so that the data packet can arrive at the terminal device 60 by the arrival reference time as much as possible. <First Embodiment of the Present Invention> In the first embodiment of the present invention,
It comprises a transfer control means 21 and an expected value setting means 22.
FIG. 4 is a diagram illustrating a packet flow according to the first embodiment of this invention. The configuration of the transfer control means 21 will be described with reference to FIG.

Reference numeral 21a is a packet determination unit that determines whether the input packet is a setup packet or a data packet, and 21b is a termination device if the destination address of the input packet is its own device, and a relay device otherwise. A device determining unit that determines that the device is a device, 21c is a data packet receiving unit that sends the received data packet to the upper layer 23, 21d is an expected value storage unit that sets an expected value for relay termination required time, and 21e is a data packet transfer A timeout determination unit that determines whether or not the delay time has exceeded the timeout time, 21g is a packet storage unit that stores the input packet, and 21f is a packet storage unit 2.
1g is a priority control packet storage unit that performs priority transfer control of packets stored in 1g, 21h is an output determination unit that controls the output order of packets according to the situation of the expected transmission reference time of the packet storage unit 21g, and 21i is an upper layer Data packet sending unit that receives the data of # 1 and sends it to the packet transfer unit 21j, 21j is a packet transfer unit that transfers the packet, and 22b is a device that determines whether the destination address of the input setup packet is its own device or another address. The determination unit, 22a receives the setup packet, and notifies the upper layer 23 or the setup information calculation unit 22d of the setting result, and the setting packet reception unit, 22d is the setup for calculating the information necessary for setting the backward setup packet. Information calculator, 22f is upper layer 2
3 or a setting packet sending unit for receiving the setup packet from the setup information calculating unit 22d and setting the expected value of the relay termination required time, 22c is the sending reference time set in the setup packet, the current reference time information, and the start end. An expected value which is calculated as an expected value of the relay termination required time from the own relay device 50 to the terminating device 60 based on the start end termination transfer time from the device 40 to the terminating device 60 and the maximum allowable delay time, and is set in the expected value storage unit 21d Calculator, 22
Reference numeral e is a timeout time setting unit that extracts the timeout time written in the setup packet and sets it in the timeout determination unit 21e. Next, the operation will be described according to the input setup packet and data packet.

When a setup packet or reverse setup packet is input to the packet determination unit 21a, the packet is sent to the device determination unit 22b, and if it is a data packet, it is sent to the device determination unit 21b. Device determination unit 2
In 2b, when the destination of the setup packet or the backward setup packet is its own device, it is sent to the setting packet receiving unit 22a, and when it is a relay device, the expected value calculating unit 22
Send to c. When the destination of the received setup packet is its own device, the setting packet receiving unit 22a passes the information (maximum allowable delay time, time allocation coefficient) necessary for generating the reverse method setup packet to the upper layer 23, and The information (maximum allowable delay time, time allocation coefficient) necessary for generating the reverse method setup packet is sent to the setup information calculation unit 22d. The setup information calculator 22d receives the information, calculates the information necessary for the backward setup packet when the device is the terminating device 60, and in the case of the relay device 50, the previous expected value for the relay terminating time. Calculate the average value of and reset. The setting packet sending unit 22f sets the sending reference time and the timeout time as they are in the setup packet from the upper layer 23, or sets the timeout time obtained by adding the timeout time to the sending reference time, and sends the setup packet to the packet transfer unit 21j.

The expected value calculation unit 22c, which has received the setup packet from the device determination unit 22b, determines the start relay time required for each flow from the difference between the transmission reference time set in the setup packet and the current reference time. Then, the expected value of the relay termination time from the relay device 50 to the termination device 60 is calculated based on the required start relay time from the initiation device 40 to the own relay device 50 and the maximum allowable delay time, and is set in the expected value storage unit 21d. Then, the packet is sent to the timeout time setting unit 22e. More specifically,
The transmission reference time is set in the setup packet transmitted from the start end device 40, and the relay device 50 calculates the difference between the current reference time when the setup packet is received and the transmission reference time, and the start end device The start relay time required from the relay device 50 to the relay device 50 is calculated, set in the expected value storage unit 21d corresponding to the flow, and the setup packet is sent to the terminating device 60.

The terminating device 60 receives the setup packet, calculates the difference between the current reference time and the transmission reference time, and obtains the starting end time required from the starting device 40 to the terminating device 60. Then, a time allocation coefficient (a result obtained by dividing the maximum allowable delay time by the start end termination required time) is calculated, the maximum allowable delay time and the time allocation coefficient are set in the backward setup packet, and the packet is returned to the start end device 40. . In each relay device 50, the required time for starting relay is calculated by multiplying the required time for starting relay by a time distribution coefficient. Then, when the expected value of the start relay required time is subtracted from the maximum allowable delay time, the relay device 50 to the terminating device 6 are subtracted.
It is possible to obtain the expected value of the relay termination required time up to 0. Although the terminating device 60 sets the maximum allowable delay time in the backward setup packet, the starting device 40 sets the maximum allowable delay time in the setup packet.
It is also possible for each relay device 50 to calculate and set the above-mentioned expected value of the relay termination required time.

The timeout setting unit 22e extracts the timeout time from the received setup packet and sets the timeout time in the timeout time setting unit 22e in association with each flow. The timeout determination unit 21e monitors the situation of the expected transmission reference time of the packet storage unit 21g, and detects the timeout time corresponding to each flow set in the timeout time setting unit 22e and the transfer delay time of the data packet corresponding to each flow. Compare
A packet whose delay is larger than the timeout time can be deleted from the priority control packet storage unit. By inserting a switch between the time-out time setting unit 22e and the time-out determination unit 21e, this function can be activated or inactivated by the user by setting the switch.

In the expected value storage unit 21d, the expected value calculation unit 22c sets the expected value of the relay termination required time from the own relay device 50 to the terminating device 60 for each flow.

The data packet sent from the device determination unit 21b is stored in the packet storage unit 21g in a FIFO (First In
First Out), the priority control packet storage unit 21
f stores the expected transmission reference time of each data packet, sorts the values of the expected transmission reference time in ascending order, and sequentially outputs from the first data packet. When a new data packet is stored in the packet storage unit 21g, it is sorted in ascending order according to the expected transmission reference time each time it is input, and is always sorted in ascending order.

The output determination unit 21h has a function of controlling the output order of the data packets according to the situation of the expected transmission reference time of the priority control packet storage unit 21f, and detects a data packet delayed from the expected transmission reference time. Then, the data packet is output with priority, and if there is no delayed data packet, the data packet is output according to the waiting order of the data packet.

The timeout time setting unit 22e monitors the expected transmission reference time in the priority control packet storage unit, compares the expected transmission reference time with the current reference time,
Priority control packet storage unit 21f determines a packet whose transfer delay time due to the difference is longer than the timeout time.
It has a function to delete from.

From the above, the relay termination required time expected value set in each relay device 50 in the setup phase,
Priority transfer control can be performed by preferentially transmitting the delay packet based on the transmission reference time and the arrival reference time.

FIG. 5 is a diagram illustrating a functional block diagram of the first embodiment of the present invention. The priority control packet storage unit 21f illustrated in FIG. 4 will be described in more detail.
The priority control packet storage unit 21f includes a sort key calculation unit 21f1 shown in FIG. 5, a priority control information sort queue,
It is composed of a clock 21z. Priority control packet storage unit 2
Reference numeral 1f is a sort key calculation unit for detecting a delayed data packet by using the packet stored in the packet storage unit 21g as a key for the expected transmission reference time, and outputting the expected transmission reference time to the priority control information sort queue, and 21f2 is an expected transmission reference time. Priority control information sort queue that sorts by using time as a key, 21h is an output determination unit that controls the output order of data packets according to the situation of the expected transmission reference time of the packet storage unit 21g, and 21j is a packet that transfers data packets The transfer unit 21z is a clock that provides the current reference time.

The sort key calculation unit 21f1 reads out the start relay required time stored in the expected value storage unit 21d based on the corresponding flow, multiplies the start relay required time by the time distribution coefficient, and calculates the start relay required time expected value. Ask for. Then, the expected value of the required start time relay time and the storage position (pointer) of the data packet in the packet storage unit 21g.
And are sent to the priority control information sort queue 21f2. The priority control information sort queue 21f2 sorts in ascending order by using the expected start relay time required value as a key each time the expected start relay required time value and the storage position of the data packet in the packet storage unit 21g are received. The output determination unit 21h compares the time when the start relay required time expected value is added to the transmission reference time of the data packet located at the head of the priority control information sort queue with the current reference time, and when the data packet is delayed. , The data packet to the packet transfer unit 2
1j, and the information about the data packet is deleted from the packet storage unit 21g and the priority control information sort queue 21f2.

According to the method described above, the delay time is corrected by preferentially transferring the delayed data packet from the data packets stored in the packet storage unit on a first-come-first-served basis, and the terminating device is arrived by the arrival deadline time as much as possible. It will be possible to control so that you can arrive at. <Second Embodiment of the Present Invention> First, the basic principle that helps to understand the second embodiment of the present invention will be described below. FIG. 3 is a diagram illustrating a packet flow according to the second embodiment of this invention. Although it is basically the same as FIG. 2, it is characterized in that a setup packet and a data packet are included in one packet (hereinafter referred to as a transfer packet). 1) Setup of priority control information In the starting device 40, the relay device 50, and the terminating device 60,
A method of setting up information necessary for priority transfer control of transfer packets will be described below.

The transfer packet sent from the start end device 40 is sent to the end device 60 including the sending reference time, the time allocation coefficient (details will be described later), and user data. Then, the transfer packet is transferred from the starting end device 40 to the terminating device 60 via each relay device 50, and the starting end time required for each flow is measured. Termination device 6
At 0, the start end termination required time is set in the reverse transfer packet and returned to the start end device 40. In the starting device 40,
The reverse transfer packet is received and the actual transfer time is extracted. Then, the maximum allowable delay time is divided by the measured transfer time to obtain the time distribution coefficient. The time distribution coefficient and the transmission reference time of the start end device are used as the transmission packet transmission reference time 2
4. Set the time allocation coefficient to 2A and send it to the terminating device 60. Each relay device 50 that has received the transfer packet
Then, the difference between the current reference time and the transmission reference time is obtained, and the start relay time required is obtained. Then, the required relay time is calculated by multiplying the start relay required time by the time distribution coefficient, and is set in the transfer control means 21 corresponding to the flow of the transfer packet. When the setting is performed, the average with the already set expected value of the start relay required time is taken and set again in the expected value storage unit 21d. The priority control information is set up by the above method. 2) Priority Transfer Control Method Next, the priority transfer control method of the transfer packet in the start end device 40, each relay device 50, and the end device 60 will be described below.

First, the starting device 40 sets a sending reference time, a time distribution coefficient, user data, and the like in the transfer packet, and sends the packet to the terminating device 60. Each relay device 50 that has received the transfer packet obtains the difference between the current reference time and the transmission reference time in the transfer packet, and obtains the delay time of the transfer packet. The delay time is compared with the expected value of the start-end relay required time, and when the value of the delay time is large, the transfer packet is targeted for priority transfer control. By performing priority control on the delay packet in each relay device 50 as necessary, priority transfer control can be performed so that the transfer packet can reach the terminating device 60 within the maximum allowable delay time.

FIG. 6 is a diagram illustrating a functional block diagram of the second embodiment of the present invention. First, the transfer control means 2
The configuration of No. 1 will be described with reference to the drawings.

The transfer control means 21 is composed of the following parts.

Reference numeral 21b is a device determination unit that determines the terminal device if the destination of the input transfer packet is its own device, and is a relay device otherwise, 21d is an expected value storage unit that sets a relay termination required time expected value, Reference numeral 21g denotes a packet storage unit that stores transfer packets in the order of input, 21f1 detects a delayed transfer packet by using the packets stored in the packet storage unit 21g as a relay expected transmission reference time, and the relay expected transmission reference time. Is output to the priority control information sort queue, 21f2 is a priority control information sort queue that sorts using the relay expected transmission reference time as a key, and 21h is a transfer depending on the situation of the relay expected transmission reference time of the packet storage unit 21g. An output determination unit that controls the output order of packets, 21j is a packet transfer unit that transfers transfer packets, and 21z is It is a clock that reports the current reference time. The expectation setting means 22 is composed of the following parts.

Reference numeral 22a denotes a setting packet receiving unit that receives the transfer packet and notifies the upper layer 23 of the setting result.
Reference numeral 22d denotes a setup information calculation unit that calculates information for setting a start end termination required time in the reverse transfer packet, 22
f is the upper layer 23 or the setup information calculation unit 22
A packet sending unit for receiving the transfer packet from d and setting information for setting an expected termination required time to an arbitrary relay device on the communication path, 22c is the sending reference time set in the transfer packet, and It is a setting packet sending unit that obtains a start end termination required time from the start end device to the end device based on the current reference time in the device and generates a backward transfer packet.

Next, the operation of priority transfer control of transfer packets will be described with reference to FIG. 1) In the case of the starting device, the upper layer 23 generates a transfer packet, and the terminating device 6
It requests the setting packet sending unit 22f to transfer to 0. The set packet sending unit 22f sets the start end time required for the transfer packet and sends the transfer packet to the packet transfer unit 21j. The packet transfer unit 21j sends the data packet to the terminating device 60. 2) In the case of a relay device When the destination of the received transfer packet or reverse transfer packet is the relay device, the device determination unit 21b sends the transfer packet to the packet storage unit 21g. In the packet storage unit 21g, if the transfer packet indicates the priority transfer within time, the transmission reference time of the transfer packet and the time distribution coefficient are sent to the expected value calculation unit 22c. Expected value calculation unit 2
In 2c, the difference between the current reference time and the transmission reference time is calculated, and the start relay time required is set in the expected value storage unit 21d in association with the current flow. Sort key calculation unit 21f1
Then, the start relay required time stored in the expected value storage unit 21d is read out based on the corresponding flow, and the start relay required time is multiplied by the time distribution coefficient to obtain the start relay required time expected value. Then, the expected start relay time required value and the storage position of the transfer packet in the packet storage unit 21g are sent to the priority control information sort queue 21f2. The priority control information sort queue 21f2 sorts in ascending order using the expected start relay time required value as a key each time the expected start relay required time value and the storage position of the transfer packet in the packet storage unit 21g are received.

The output determination unit 21h compares the time when the start relay required time expected value is added to the transmission reference time of the transfer packet located at the head of the priority control information sort queue 21f2 with the current reference time, and the transfer packet is delayed. When the packet is being transferred, the transfer packet is sent to the packet transfer unit 21j,
The packet storage unit 21g stores information about the transfer packet,
Delete from the priority control information sort queue.

The packet transfer unit 21 j sends the transferred packet to the terminating device 60. 3) In case of terminating device When the destination of the received transfer packet or reverse transfer packet is the terminating device, the device determining unit 21b sends the transfer packet to the setting packet receiving unit 22a. The set packet receiving unit 22a sends the transfer packet or the reverse transfer packet to the upper layer 23. Further, the set packet receiving unit 22a sends the set transfer unit 22f the start end time required for the backward transfer packet triggered by the received transfer packet. Setting packet transmitter 22
f sets the start end time required for the transfer packet and sends it to the packet transfer unit 21j. The packet transfer unit 21j sends the transferred packet to the terminating device 60.

In the above description, the current reference time is provided from the clock 21z.

By the above method, the packet storage unit 21
It is possible to correct the delay time by preferentially transferring the delayed transfer packet from the transfer packets stored in the g first-come-first-served basis, and control so that the packet can reach the terminal device by the arrival deadline time as much as possible. Becomes

[0071]

As described above, according to the present invention, 2
In a relay device accommodating one or more lines, when packets are input in burst from one line, transfer of packets from the other line is delayed. The present invention is thus
The transfer delay time is corrected as much as possible by prioritizing the transfer control of the delayed data packet so that it falls within the maximum allowable delay time set for the flow of the transfer delay packet, and it is possible to improve the transfer quality of the packet. is there.

[Brief description of drawings]

FIG. 1 is a diagram illustrating a basic principle diagram of the present invention.

FIG. 2 is a diagram illustrating a packet flow according to the first embodiment of this invention.

FIG. 3 is a diagram illustrating a packet flow according to a second embodiment of this invention.

FIG. 4 is a diagram for explaining a functional block diagram of the first embodiment of the present invention (No. 1).

FIG. 5 is a view for explaining the functional block diagram of the first example of the present invention (Part 2).

FIG. 6 is a diagram illustrating a functional block diagram of a second embodiment of the present invention.

FIG. 7 is a diagram for explaining the occurrence of packet transfer delay.

[Explanation of symbols]

1, 2, 3, 4 flow 10, 20, 30 Relay device 21 transfer control means 22 Expected value setting means 23 Upper layer 24 Transmission standard time 25 Timeout identifier 26 Maximum allowable delay time 27,2A time allocation coefficient 28 Arrival standard time identifier Priority transfer within 29 hours 2B data 40 Starting device 50 relay device 60 Terminator

Claims (14)

(57) [Claims] 1. A packet received on a network
In the priority transfer control device that relays to the desired destination, when relaying the received setup packet,
Calculate the start relay time required by the setup packet.
Corresponding to the flow of
Sends a packet and receives a reverse setup packet.
If you want to relay
The time required for the relaying at the start end held and the set-up in the reverse direction
Starting from the product of the time allocation coefficient set in the packet
Obtain the expected value of the required connection time, and set the reverse setup packet.
Maximum allowable delay time set in the network and the required start relay time
Calculate the difference from the expected value as the expected value of the relay termination required time,
Corresponding to the flow described above, the relay terminal required time period
The waiting value, the time allocation coefficient, and the maximum allowable delay time
Each of them is held and sent out, and when the received data packet is relayed, it is received.
Detect and detect delayed data packets from data packets
The delayed data packet that has been
Data packets other than data packets can be sent normally.
And a priority transfer control device. 2. In the data packet according to claim 1.
The largest delay time among the received delay data packets
Characteristic that threshold delay data packets are transferred with priority
Priority transfer control device. 3. The start time relay required time period according to claim 1.
The waiting value is, when relaying the setup packet,
The current reference time of the device and the setup packet
Start relay required from the difference from the transmission reference time set in the
Calculate the time, and correspond to the time required for the start relay and the flow.
The start point relay station by the product of the time allocation coefficient held by
Priority transfer control device characterized by obtaining expected time required value
Place 4. The relay termination required time period according to claim 1.
The waiting price was held in the own device corresponding to the flow.
The maximum allowable delay time and the expected value of the start relay required time
A priority transfer control device characterized by being obtained from the difference between 5. The apparatus according to claim 3, wherein the apparatus is held in advance in correspondence with the flow.
Between the maximum allowable delay time and the expected value
The first relay termination required time expected value is calculated from the difference, and the first relay termination required time expected value is calculated.
The expected value of the relay termination required time corresponds to the flow and
Less than the expected value for the second relay termination required time held by the device
If the data packet is
Priority transfer control as
If there is no transfer control means to control transfer normally
Priority transfer control device characterized by. 6. The current reference time of the device itself and the received data packet according to claim 1.
Start relay time required from the difference between the transmission reference time set in
And the flow of the data packet at the start relay time required.
Corresponding to the time distribution coefficient held in the device itself or
From the product of the time allocation coefficient set in the data packet
During the first start, the expected value for the first start relay required time is calculated.
The expected duration time value corresponds to the flow of the data packet.
The expected value of the second start relay required time held by the device
Detected as the delayed data packet when
Priority transfer control characterized by being subject to priority transfer control
Your device. 7. The device according to claim 1 , wherein the current reference time of the device itself and the received data packet.
Start relay time required from the difference between the transmission reference time set in
And the flow of the data packet at the start relay time required.
Corresponding to the time distribution coefficient held in the device itself or
From the product of the time allocation coefficient set in the data packet
Obtain the expected value of the time required for the start relay and set it in the data packet
Of the determined transmission reference time and the expected value of the start relay required time
The relay expected transmission reference time is calculated from the sum, and the relay expected transmission base is calculated.
If the sub time is ahead of the current reference time, the data
Priority transfer control using packets as the delay data packets
A priority transfer control device characterized by: 8. The current reference time of the device itself and the received data packet according to claim 1.
Start relay time required from the difference between the transmission reference time set in
And the flow of the data packet at the start relay time required.
Corresponding to the time distribution coefficient held in the device itself or
From the product of the time allocation coefficient set in the data packet
Obtain the expected value of the time required for the start relay and set it in the data packet.
Specified arrival reference time identifier and expected start time required
Calculate the expected value for the relay termination required time from the difference between
If the expected end time is ahead of the current reference time
The data packet as the delayed data packet.
A priority transfer control device characterized in that it controls transfer in advance. 9. The odor according to any one of claims 5 to 8.
The transmission reference time and time set in the data packet
Sum of out time or set in the data packet
Either of the time-out times
And the time-out time was later than the current reference time
Sometimes, the data packet is discarded
Priority transfer control device. 10. A network is provided from a desired source on the network.
When a data packet addressed to itself is received by the priority transfer control device that receives the packet,
The packet to the upper layer and set it up for the device itself.
When a packet is received, the current reference time of the device itself
And the transmission reference time set in the setup packet
Calculate the start and end required time from the difference between
Time is calculated by dividing the delay time by the time required for the start and end.
Backward allocation including the time allocation coefficient
A special feature is that it generates an up packet and sends it back to the initiating device.
Priority transfer control device. 11. The reverse settler according to claim 10.
In the return of a packet, the maximum allowable delay time is added to the reverse setup packet.
A priority transfer control device comprising: 12. The method according to claim 10 or 11, wherein the current reference time and the setup packet are set.
The time required for the start and end is calculated from the difference between the
The time required for the start and end is added to the reverse direction setup packet.
A priority transfer control device characterized by inclusion. 13. Priority transfer of packets on a network
When sending a transfer packet , the priority transfer control device that performs control sends it to the transfer packet.
Installed in advance according to the reference time and the flow of the transfer packet.
If the time allocation coefficient held in the storage is set and sent, and the transfer packet is relayed, the current reference time and reception
Is it a difference from the transmission reference time set in the transfer packet?
Start relay time required from the
Expected first start relay required time from product with time allocation coefficient
The value is obtained, and it is already stored in the own device corresponding to the above flow.
It compares with the expected value of the second start relay required time,
If the second expected value of the start relay time is small,
If the packet is sent out with priority, otherwise the transfer packet is sent normally.
When sending a packet and receiving a transfer packet, the
From the difference with the transmission reference time set in the transmission packet,
Calculate the time required for the end and add it to the generated reverse transfer packet.
Set the start and end required time and send the reverse transfer packet.
When returning to the origin and relaying the backward transfer packet
Sends the received backward transfer packet to the originating device.
Maximum allowable delay when outgoing and reverse transfer packets are received
Time end set in the backward transfer packet
Divide by the required time to obtain the time distribution coefficient, and
The coefficient is paired with the reverse flow of the reverse transfer packet flow.
Prioritized transfer control characterized by being held by the device itself
apparatus. 14. The method according to claim 13, wherein when the transfer packet is relayed, the current reference time and the
Start from the difference from the transmission reference time set in the transfer packet
The relay required time is calculated, and the start relay required time and the previous start
Calculate the average value with the relay required time, and based on this average value the start point
Priority transfer characterized by calculating expected value of relay required time
Transmission control device.