JP2003032284A - Packet exchange apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To quickly change-over a switch. SOLUTION: Transmission sections 200 and 201, at an input interface section 20 add an inspection field for error detection to a packet, which is received from a line 40 via an input-processing section 205, and outputs it to doubled switching sections 10 and 11. Inspection sections 300, 301 of an output interface section 30 inspect the inspection field of the packet received from the switch sections 10 and 11 for errors, and a selection control section 304 controls a selector 303, so that a packet having no errors is sent to a line 50.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a packet switching device for exchanging packets, and more particularly to a packet switching device for exchanging packets by means of a redundant switch section.

[0002]

2. Description of the Related Art In recent years, due to the spread of the Internet, the performance of devices constituting the Internet has been improved, the function has been improved, and the price has been reduced. It is becoming more and more configured using equipment. However, a high degree of reliability, ie resistance to failures, remains unsolved. It is expected that even in the future, high reliability will be required for Internet devices that form part of high reliability networks. A packet switching device is used for switching packets used for data transmission on the Internet or the like (for example, Japanese Patent Laid-Open No. 5-560).
65, JP-A-7-143138, JP-A-8
-251118, JP-A-9-284300, and JP-A-11-88338).

FIG. 5 is a diagram showing a packet switching device which has been conventionally used, and is an example of a packet switching device in which a switch section is duplicated. As shown in FIG. 5, the packet switching device in which the switch section is duplicated has two switch sections 1
0, 11, (n + 1) input interface units 20,
21, ..., 2n, (n + 1) output interface units 30, 31, ..., 3n.

The input interface unit 20 and the output interface unit 30, the input interface unit 21 and the output interface unit 31, ..., The input interface unit 2n and the output interface unit 3n are used as a pair for input and output of the line. Input interface unit 2
0, 21, ..., 2n are input lines 40, 41, respectively.
... receives a packet via 4n and transmits the received packet to the switch unit 10 and the switch unit 11, respectively. The switch units 10 and 11 respectively transfer the received packets to the line interface units 30, 31, ..., 3n.

Explaining with focus on one input interface unit 20, the input interface unit 20 is the input line 4
The packet is received via 0, and the received packet is sent to the switch unit 10 and the switch unit 11. The switch unit 10 outputs the packets received from the input interface unit 20 to the output interface units 30, 31, ..., 3
Send to any of n. Similarly, the switch unit 11 transmits the packet received from the input interface unit 20 to any of the output interface units 30, 31, ..., 3n.

Which output interface unit 30, 31, ..., 3n the switch unit 10, 11 transfers the packet received from the input interface unit 20 to is transferred by a well-known method. Although the description is omitted, for example, the input interface unit 20 analyzes the header information of the received packet and refers to the routing table of the input interface unit 20 itself to determine which output interface unit 30,
.. is determined to be transferred to 3N, and information (transfer destination information) designating the output interface unit of the transfer destination is transferred to the switch units 10 and 11 together with the packet. The received packet is transferred to the designated output interface unit according to the transfer destination information.

Output interface units 30, 31, ...
.. 3n refers to the packets received from the switch unit 10 or the switch unit 11 for the corresponding output lines 50, 51 ,.
..Output to 5n. Line interface units 21, 2
The same applies to 2, ..., 2n. In this way, the packet switching device has the input lines 40, 41, ..., 4n.
Packets input from the output lines 50, 51, ...
-Operates to output to any of 5n.
In FIG. 5, the input interface units 20, 21, ...
.., 2n and output interface units 30, 31, ...
Although 3n is used as another functional unit, since most of the physical connection destination devices are the same, both functional units are often mounted on the same card.

The packet switching apparatus shown in FIG.
Alternatively, one of the switches 11 is operated in the "act" state and the other is in the "standby" state. From the input interface units 20 to 2n to the switch unit 10 and the switch unit 1
Packet is transmitted to both of
And the switch unit 11 are both output interface units 30.
3n, but packets transmitted through both switch units 10 and 11 are all output lines 50 to
The output interface units 30 to 3n do not output to each of the 5n, and transfer only packets that arrive from the switch unit in the act state, and do not transfer packets that arrive from the switch unit in the standby state. There is also a method in which the input interface units 20 to 2n send packets only to either the switch unit 10 or the switch unit 20. In this case, the state of the switch unit through which packets do not pass is called cold standby, and the state described above is called hot standby. Since the packet switching device in such an operation mode is well known, its description is omitted.

The output interface units 30 to 3n recognize which of the switch unit 10 and the switch unit 11 is in the standby state and which is in the act state. As a method of knowing the act / standby state of the switch units 10 and 11, for example, the switch unit 10 and the switch unit 11 determine their own states (whether the act state or the standby state) to the output interface units 30 to 3n. This is done by transmitting a status notification signal for notification.

Next, the operation of system switching will be described. First, it is assumed that the switch unit 10 is in the act state and the switch unit 11 is in the standby state. Output interface unit 30
3 to 3n output only the packets transferred from the switch unit 10 to the output lines 50 to 5n, but when a failure occurs in the switch unit 10, a failure detecting means (Fig. The failure is detected by (not shown), and the switch unit 10 is changed from the act state to the standby state. The switch unit 11 detects that the switch unit 10 has failed and shifts from the standby state to the act state. In this way, the line interface units 30 to 3n
Stops packet reception from the switch unit 10 and starts packet reception from the switch unit 11.

When the switch unit 10 is in the standby state and the switch unit 11 is in the act state, the switch unit 1
When a failure occurs in No. 1, the failure is detected by failure detection means (not shown) provided in the switch unit 11, and the switch unit 11 is changed from the act state to the standby state. The switch unit 10 detects that the switch unit 11 has failed and shifts from the standby state to the act state. The line interface units 30 to 3n stop the packet reception from the switch unit 11 and start the packet reception from the switch unit 10. By doing so, when one of the switch units 10 and 11 which transfers packets in the two switch units 10 and 11 fails,
Since the other switch units 10 and 11 immediately transfer the packet, it is possible to realize a packet switching device that is resistant to failure.

[0012]

However, in the above-mentioned conventional packet switching apparatus, a failure is detected and reflected in the act / standby state switching of the switch section, whereby the output interface section selects the switch section. Since control is performed, there is a problem that it takes time to switch the switches. Also, since the switching of the switch unit is performed only by checking the act / standby state of the switch unit, there is a possibility that the packet being transferred from the switch unit may be divided by the switching.

An object of the present invention is to make it possible to quickly switch a switch. Another object of the present invention is to prevent fragmentation of transfer packets.

[0014]

According to the present invention, the packet received from the transmission line by the receiving means is output to the output means via the duplicated first and second switch portions,
In a packet switching device in which the output unit selects one of the packets received from the first and second switch units and sends the packet to a transmission line, the receiving unit detects an error in the packet received from the transmission line. When the error is detected in the inspection field of one of the packets received from the first and second switch units, the output unit outputs the error from the switch unit having no error. A packet switching device is provided, which is characterized in that the received packet is sent to the transmission path. The receiving means adds a check field for error detection to the packet received from the transmission path and outputs the packet. The output means are the first and second
If an error is detected in the check field of any of the packets received from the switch unit, the packet received from the error-free switch unit is sent to the transmission path.

Here, the output means includes the first and second output means.
Error in the inspection field according to the inspection results of the first and second inspection units, which are provided corresponding to the switch unit of FIG. Selection unit for outputting a selection signal for selecting a packet having no error, and in response to the selection signal, a packet having no error in the first and second switch units is selected and is transmitted to a transmission line. It may be configured to include a selector for sending.

Further, the selection control unit is configured to operate the first and second
If any of the inspection units detects that there is no error in the packet, the selector is operated so as to send the packet from the switch unit in the active state among the first and second switch units to the transmission path. It may be configured to control. Further, when the selector switches the packet from the first switch unit and the packet from the second switch unit and sends the packet to the transmission path, the selector may switch at the head of the packet.

Further, the receiving means has first and second transmitting portions provided corresponding to the first and second switch portions, respectively, and the first and second transmitting portions are transmitting portions. It is also possible to add a check field for error detection to the packet received from the route and send it to the corresponding first and second switch sections. Further, the receiving means detects a failure in a path passing through the first and second switch parts, and
The transmission unit provided corresponding to the second switch unit has a failure detection unit that outputs a failure detection signal indicating that a failure has been detected, and the first and second transmission units include the failure detection signal. A signal may be received, and a signal indicating an error may be added to the check field and transmitted.

[0018]

1 is a block diagram of a packet switching apparatus according to a first embodiment of the present invention, in which the same parts as those in FIG. 5 are designated by the same reference numerals. The packet switching device according to the first embodiment is similar to that shown in FIG.
Although a plurality of input interface units and a plurality of output interface units are connected to 0 and 11, respectively,
In FIG. 1, only one set of the input interface unit 20 and the output interface unit 30 and the switch units 10 and 11 in the packet switching apparatus shown in FIG. 5 are shown.

In FIG. 1, an input interface section 20 as an input means is a functional section for receiving a packet. Further, the output interface unit 30 as an output means is a functional unit for transmitting a packet. The input interface unit 20 includes an input processing unit 205 and a plurality of transmitting units 200 and 201. The output interface unit 30 includes a plurality of inspection units 300 and 301 and a selector 30.
3. A selection control unit 304 is provided. The input interface unit 20 is connected to the plurality of packet switch units 10 and 11, and transmits packets to both switch units 10 and 11. The output interface unit 30 is connected to the packet switch units 10 and 11 and receives packets from both packet switch units 10 and 11.

The operation of the packet switching apparatus according to the first embodiment will be described below. First, the operation of the input interface unit 20 will be described. The input processing unit 205
The packet received via the line 40 is inspected for errors in the packet header, and then output to the transmission units 200 and 201. For example, if the received packet is an IP (Internet Protocol) packet, TT
The L (survival time: Time To Live) value is subtracted, and the checksum is recalculated and added. In addition, processing such as reading the output address and checking the output interface to which the packet is to be transferred is performed.

The transmission units 200 and 201 are the input processing unit 20.
A field for detecting an error is added to the packet received from the line 40 via 5 and output to the corresponding switch units 10 and 11, respectively. Hereinafter, this will be referred to as an inspection field. For example, as shown in FIG. 2, a check field is added to the end of the packet, and a checksum for all the data included in the packet is added to the packet. The checksum is an example, and it is also possible to include a parity calculation result or a CRC calculation result. In this way, the packets with the inspection field are transmitted from the transmission units 200 and 201 to the corresponding switch units 10 and 11, respectively.

The switch section 10 and the switch section 11 perform a switching operation and transmit a packet to a desired output interface section. In FIG. 1, only the output line 50 is shown for the sake of simplicity.
It is assumed that all the packets from 0 and 11 are transferred only to the output interface unit 30. The switch units 10 and 11 have corresponding inspection units 300 and 3 respectively.
The packet is output to 01.

Next, the operation of the output interface section 30 will be described. In the output interface unit 30, the packet received from the switch unit 10 is input to the inspection unit 300, and the packet received from the switch unit 11 is input to the inspection unit 301. The inspection unit 300 includes the transmission unit 200 described above.
The normality of the inspection field added is checked by referring to the inspection field and the packet contents added in. If the inspection result is normal, an inspection signal indicating that the packet is normal is transmitted to the selection control unit 304. Similarly, the inspection unit 301 refers to the inspection field and the contents of the packet added by the transmission unit 201 described above, and inspects the normality of the inspection field. If the inspection result is normal, an inspection signal indicating that the packet is normal is transmitted to the selection control unit 304.

It is assumed that the selection control section 304 recognizes which of the switch sections 10 and 11 is in the act state or the standby state. For example, as shown in the example of FIG. 5, the act or standby state of the switch units 10 and 11 can be known from the signal indicating the act or the standby transmitted from the switch unit 10 and the switch unit 11. The selection control unit 304 transmits a selection signal to the selector 303 based on the inspection signals transmitted from the inspection units 300 and 301 and the states of the switch unit 10 and the switch unit 11.

The selector 303 selects either the inspection unit 300 or the inspection unit 301 according to the selection signal transmitted from the selection control unit 304, and transfers the packet to the output line 50. The timing at which the selection state of the selector 303 is switched is always at the head of the packet, and the selection state is not switched in the middle of the packet. This makes it possible to prevent the packet being transferred from being divided by switching. Selection control unit 3
The method of determining the type of the selection signal output by 04 is as follows. If the inspection results of both the inspection unit 300 and the inspection unit 301 are normal, the packet from the inspection unit connected to the switch unit in the act state is selected, and if only one is normal, the switch unit is in the act state. The packet is received from the inspection unit whose inspection result is normal regardless of whether the packet is in the standby state or in the standby state.

A table of this selection logic is shown in FIG. In FIG. 3, 0 system is a system passing through the switch unit 10, 1 system
The system indicates a system that passes through the switch unit 11. As shown in FIG. 3, the 0-system inspection by the inspection unit 300 and the inspection unit 3
If both inspection results of the 1 system by 01 are normal, the switch section in the act state (if 0 system is act and 1 system is standby, switch section 10, 0 system is standby and 1 system is act) In the case of, the packet from the inspection unit connected to the switch unit 11) is selected and the output line 5
Output to 0. If only one is normal, the inspection unit connected to the switch unit of the system in which the inspection result is normal regardless of which of the 0 system and the 1 system is in the act state or the standby state. Selects the packet from and outputs to the output line 50.

Next, the mutual work of the switch units 10 and 11, the input interface unit 20, and the output interface unit 30 will be described. Here, it is assumed that the switch unit 10 is in the act state and the switch unit 11 is in the standby state. For example, when some kind of failure such as disconnection occurs on the transmission line between the switch unit 10 and the output interface unit 30, the value of the packet or the inspection field is not normal on the output interface unit 30 side. In this case, even if the switch unit 10 is in the act state,
As a result, the packet from the switch unit 11 is output line 5
It is output to 0.

Next, it is assumed that some failure occurs inside the switch section 10. In the case of the failure of the route passing through the packet, some error occurs in the inspection field or the packet, so that the switch unit 10 and the output interface unit 30 perform the same operation as the failure example described above. That is, even if the switch unit 10 is in the act state, the packet from the switch unit 11 is output to the output line 50 as a result. However, if the failure is other than that, the check field and the packet may not be erroneous. In order to prevent such a situation, when some failure is detected by the failure detecting means (not shown) provided in the switch section 10, an error pattern is artificially generated in the inspection field. By doing so, the output interface unit 30 detects an error from the switch unit 10, and as a result, switch system switching (switching from the switch unit 10 to the switch unit 11) occurs.

FIG. 4 is a block diagram of a packet switching apparatus according to the second embodiment of the present invention, and the same parts as those in FIG. 1 are designated by the same reference numerals. The second embodiment is different from the first embodiment in that the input interface unit 20 side has a function of artificially mixing an error in a check field as realized by the switch unit 10. There is, and as a configuration therefor, the input interface unit 20
Is provided with the failure detection unit 202. The description of the same parts as those of the first embodiment will be omitted, and the operation will be described only for the differences.

When the failure detecting section 202 detects that a failure has occurred on the switch section 10 side or the switch section 11 side, the transmitting section 200 or the transmitting section 20 on the path where the failure has occurred.
For 1, the failure detection signal indicating that a failure has occurred is output. The transmitting unit of the transmitting unit 200 and the transmitting unit 201, which receives the failure detection signal, mixes an error in the inspection field and transmits it. As a result, the output interface unit 30 selects a packet having an inspection field in which no error is mixed and outputs it from the selector 303 to the line 50. This allows the input interface unit 30 side to specify which of the switch units 10 and 11 has passed the packet to the output interface unit 30. If this function is used, the switch unit 1
Even if the states 0 and 11 are not determined in advance, which switch unit 10,
It is also possible to specify whether 11 is used as an act or a standby.

As described above, the packet switching apparatus according to each of the embodiments outputs the packet received from the transmission line by the receiving means to the output means via the duplicated first and second switch sections. In the packet switching device in which the output unit selects one of the packets received from the first and second switch units and sends it to the transmission line, the reception unit includes an error in the packet received from the transmission line. When an error is detected in the inspection field of one of the packets received from the first and second switch units, the output unit adds and outputs an inspection field for detection. Since the packet received from the switch unit is sent to the transmission path, any of the switch units 10 and 11 can be autonomously operated by the output interface units 30 to 3n. Because it can determine whether to select the packet to be al transfer, switching delays by the state determination of the switch unit using software like is not generated, rapid switching system switching can be realized. Also,
A packet selection circuit can be realized with a simple configuration, a complicated system switching control circuit is not required, and the hardware cost for configuring the packet switching device can be reduced. Furthermore, since the switching control is executed for each packet, it is possible to realize the switching of the switching system in which the packet loss due to the switching is small.

[0032]

According to the present invention, it is possible to realize a quick switch system switching. In addition, a complicated system switching control circuit is not needed, and the hardware cost can be reduced. Furthermore, it becomes possible to realize switch system switching with less packet loss due to switching.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a first exemplary embodiment of the present invention.

FIG. 2 is a diagram showing a packet used in the embodiment of the present invention.

FIG. 3 is a diagram for explaining an operation of implementing the present invention.

FIG. 4 is a block diagram showing a configuration of a second exemplary embodiment of the present invention.

FIG. 5 is a block diagram showing a conventional packet switching device.

[Explanation of symbols]

10, 11 ... Switch sections 20-2n ... Input interface sections 30-3n as input means ... Output interface sections 40-4n as output means ... Input lines 50-5n ... Output lines 200, 201 ... Transmission unit 202 ... Failure detection unit 205 ... Input processing unit 300, 301 ... Inspection unit 303 ... Selector 304 ... Selection control unit

Claims (6)

[Claims] 1. A packet received from a transmission line by a receiving means is output to an output means via a duplicated first and second switch section, and the output means outputs from the first and second switch sections. In a packet switching device that selects any of the received packets and sends out to a transmission path, the receiving means adds an inspection field for error detection to the packet received from the transmission path and outputs the packet, and the output means When an error is detected in the check field of any of the packets received from the first and second switch units, the packet received from the switch unit having no error is sent to the transmission line. Packet switching device. 2. The output means is provided corresponding to the first and second switch sections, and first and second check sections for performing error detection using the check field, and the first and second check sections. Two
Selection control unit for outputting a selection signal for selecting a packet having no error in the inspection field according to the inspection result of the inspection unit, and the first and second response units in response to the selection signal.
2. The packet switching apparatus according to claim 1, further comprising a selector that selects a packet having no error in the switch unit of 1 and sends it to a transmission line. 3. The selection control unit is in an active state of the first and second switch units when both the first and second check units detect that there is no error in the packet. 3. The packet switching device according to claim 2, wherein the selector is controlled so that the packet from the switch unit is sent to the transmission path. 4. The selector, when switching the packet from the first switch unit and the packet from the second switch unit and transmitting the packet to the transmission path, switches at the head of the packet. The packet switching device according to item 2 or 3. 5. The receiving means has first and second transmitting portions provided corresponding to the first and second switch portions, and the first and second transmitting portions are transmitting portions. 5. The packet switching device according to claim 1, wherein a packet received from the route is added with a check field for error detection and is sent to the corresponding first and second switch units. . 6. The receiving means detects a failure in a path passing through the first and second switch parts, and detects the first and second switch parts.
The transmission unit provided corresponding to the switch unit has a failure detection unit that outputs a failure detection signal indicating that a failure has been detected, and the first and second transmission units output the failure detection signal. 6. The packet switching device according to claim 5, wherein the packet switching device receives the signal, adds a signal indicating an error to the check field, and transmits the signal.