JPH10178428A - Packet communication network - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the installation cost by accumulating the packets of a number suited to the bit speed of a destination communication network according to the contents of an incoming packet header and adding a new header so as to accelerate a header processing rate. SOLUTION: This packet communication network consists of the subscribers' networks 4-11 to 4-14 of 150Mb/S bit rate and the local networks 4-21 and 4-22 of 600Mb/S bit rate housing this. In addition, the network is provided with rate conversion parts 511 to 514 mutually converting the bit rates of packets passing through between the subscribers' networks and the local networks. Then the parts 511 to 514 make the packet lengths of the networks 4-11 to 4-14 and the networks 4-22 and 4-22 respectively fixed lengths. In addition a header re-editing part is provided to set the bit length of a packet so as to make one packet time nearly equal between these two communication networks by this. Consequently, one packet of the network 4-11 to 4-14 includes the four packets of the networks 4-21 and 4-22 and the newly added header.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention is used for packet communication. The present invention relates to an asynchronous transfer mode (ATM: Asynchronou).
s Transfer Mode) Suitable for communication.

[0002]

2. Description of the Related Art As a technique for transmitting and receiving data by dividing all data into fixed-length packets, asynchronous transfer mode (hereinafter referred to as ATM) communication is known. Fixed-length packets are generally called cells. Here, a fixed-length packet refers to a packet in which the number of bits constituting the packet is uniquely determined.

A conventional technique will be described with reference to FIG. FIG. 6 is a diagram showing a conventional ATM exchange. The operation of the conventional ATM exchange will be described with reference to FIG. The ATM exchange performs hardware routing based on the header information of the cell. The detailed operation principle is described in, for example, "Point Illustrative Scheme, Standard ATM Textbook (ASCII Publishing)" and the like, and is well known.

In a conventional ATM switch, as shown in FIG. 6A, a 150 Mb / S ATM switch 1-1 (here, an input / output line having a speed of 150 Mb / S is referred to as such). 2.7 μS (150 Mb / S
1 cell is processed in (time to transfer 53 bytes in (1))
The time for processing a cell is called one cell time.)

On the other hand, as shown in FIG.
In the b / S ATM switch 1-2, one cell time is about 0.1.
69 μS. Therefore, each ATM of 600 Mb / S
In the exchange 1-2, all functions required for one cell must be realized within 0.69 μS.

[0006]

[0006] One cell time is 0.69 µm.
In S, it is necessary to analyze the contents of the header and not only change the contents of the header, called header conversion, determine the route based on the contents of the header, but also monitor cell traffic called UPC (Usage Parameter Control). Must. Therefore, the higher the speed of the ATM switch, the higher the speed of header processing required, and at the same time, the higher the transmission speed of the transit switch, the more VCI / V.
You have to deal with PIs, that is, connections.

Therefore, for example, in consideration of header conversion, it is necessary to access and process a memory storing a large amount of VCI / VPI in a shorter time.

More specifically, an ATM of 150 Mb / S
Assuming that the exchange needs to process 10 connections for 100 cells per second, a 2.4 Gb / S ATM exchange processes 160 connections at 1600 cells per second. That is, 16 times the memory amount is accessed in 1/16 of the time.

Generally, a memory (RAM) having a large capacity has a short access time, and as a result, there is a disadvantage that an economically high-speed ATM switch cannot be realized.

SUMMARY OF THE INVENTION The present invention has been made in view of such a background, and an object of the present invention is to provide a packet communication network capable of reducing a packet processing speed in a high-speed switch. An object of the present invention is to provide a packet communication network that can reduce the cost of installing a communication network. An object of the present invention is to provide a packet communication network capable of improving the throughput of a communication network.

[0011]

According to the present invention, the time length of one packet is equivalently substantially constant, and each exchange performs necessary processing within the time length of one packet. The most important feature of a packet for a high-speed switch is that a plurality of small (53-byte) packets are entered, and routing is performed by writing the VPI common to the routes of the plurality of packets in a header portion or the like. And

Compared to the conventional technology, the actual number of bytes of a packet, information constituting a high-speed packet, the number of packets that must be processed in a unit time, and the equivalent number of connections are different.

That is, according to the present invention, the bit rate is r ₁ b
/ S, a second communication network accommodating a plurality of the first communication networks and having a bit rate of r ₂ b / S, the first communication network and the second communication network. And a speed conversion unit for converting the bit rate of a packet passing between the network and the network. It is a feature of the present invention that the speed conversion unit has a configuration in which the packet length of the first communication network and the packet length of the second communication network are each a fixed length, and one packet time (one packet is processed). (The time required to perform one packet is referred to as one packet time) between the two communication networks.

Here, "substantially equal" means that at least the header can be processed by a device having the same processing capability in substantially the same time. For example, one packet time of the first communication network is reduced to one packet time. When L ₁ and one packet time of the second communication network are L ₂ , [L ₁ : L ₂ ] is [1:
It is appropriate to set between 3] and [1: (1/3)].

It is preferable that one packet of the second communication network includes n packets (n = r ₂ / r ₁ ) of the first communication network and a newly added header.

The speed conversion means includes means for distributing the packet for each route according to the header content of the packet arriving from the first communication network, and buffers provided for each route. When a number of packets conforming to the bit rate of the destination communication network are stored in the buffer, the plurality of packets are sequentially read from the buffer, and a new packet representing a common route of the plurality of packets is provided in the first packet. And a header reediting section (14-16) for adding a header.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The construction of an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a diagram showing a multi-stage communication network. FIG. 2 is a block diagram of the speed converter.

According to the present invention, a subscriber network 4-11 to 4-14 having a bit rate of 150 Mb / S, and the subscriber network 4-
Area networks 4-21 and 4-22 accommodating 11 to 4-14 and having a bit rate of 600 Mb / S;
-11～4-14 and a speed conversion section 5 _{11-5 14} and packet communication network having a for converting the bit rate of packets to each other passing between the local network 4-21 and 4-22.

Here, the feature of the present invention is that the speed conversion units 5 _{11 to} 5 ₁₄ are configured to convert the packet lengths of the subscriber networks 4-11 to 4-14 and the packet lengths of the local networks 4-21 and 4-22. Header reediting units 14 to 16 as means for setting the bit length of a packet so that one packet time is substantially equal between the two communication networks.
Is included.

Packet 1 of the subscriber networks 4-11 to 4-14
There are four packets of the regional networks 4-21 and 4-22 (4
= 600/150) and the newly added header.

[0022] In more detail the structure of the speed converting unit 5 _{11-5 14,} as shown in FIG. 2, the subscriber network 4-11～
A distribution circuit 10 as means for distributing each packet according to the header content of the packet arriving from 4-14, and buffers 11 to 1 provided for each path.
3 and the destination local network 4-2 in the buffers 11-13.
When a number of packets conforming to the bit rates of 1 and 4-22 are accumulated, the plurality of packets are sequentially read from the buffers 11 to 13 and a new packet representing a common route of the plurality of packets is added to the first packet. Header reediting sections 14 to 16 for adding headers;

The description between the local networks 4-21 and 4-22 and the relay network 4-3 can be made in the same manner as described above.

That is, according to the present invention, the bit rate is 600
Mb / S regional networks 4-21 and 4-22, relay networks 4-3 accommodating these regional networks 4-21 and 4-22 and having a bit rate of 2.4 Gb / S, and regional networks 4-21. −
21 and is a 4-22 a packet communication network that the bit rate of packets that pass through and a speed converting section 5 ₂₁ and 5 ₂₂ which converts mutually between the relay network 4-3.

[0025] Here, it is an aspect of the present invention, the speed converting unit 5 ₂₁ and 5 _22, local networks 4-21 and 4-
22 and the packet length of the relay network 4-3 are respectively fixed lengths, and the header length as a means for setting the bit length of the packet so that one packet time is substantially equal between the two communication networks. It includes editing units 14 to 16.

One packet of the regional networks 4-21 and 4-22 is composed of four packets of the relay network 4-3 (4 = 2400/6).
00) and the newly added header.

[0027] To describe the structure of the speed converting section 5 _{21-5 23} in more detail, as shown in FIG. 2, the packet according to the header content of the packet coming from local networks 4-21 and 4-22 catalog A sorting circuit 10 as means for separately sorting, and buffers 11 to 11 provided for each route.
13 and the destination relay network 4-
When a number of packets conforming to the bit rate of 3 are accumulated, the plurality of packets are sequentially read from the buffers 11 to 13 and a new header indicating a common route of the plurality of packets is added to the first packet. Header reediting sections 14 to 16 are included.

Although the embodiment of the present invention has a three-stage hierarchical structure as shown in FIG. 1, it can be described as having a multi-stage structure.

Next, the operation of the embodiment of the present invention will be described. Subscriber terminal 3 when performing the communication ₁ from to 3 _2, exchange of 150 Mb / S of subscriber network 4-11 (which VPI /
(Uniquely determined by the VCI) transfers the packet to the regional network 4-21 according to the route information "G" included in the header information of the packet. FIG. 3 is a diagram showing the format of the packet. In the subscriber network 4-11, as shown in FIG. 3A, 2.7 .mu.S of packet .alpha.

The local network 4-21 has a subscriber line 4-1 because the bit rate of the line accommodated therein is 600 Mb / S.
The speed is four times faster than that of No. 1 and four packets can be transferred in 2.7 μS. Accordingly, the speed conversion section 5 ₁₁ of subscriber network 4-11, four successive packets, as shown in FIG. 3 (b) α, β, γ, using [delta].

[0031] In the sorting circuit 10 of the speed conversion section 5 ₁₁ of subscriber network 4-11, the packet according to route information "G" to distribution circuit 10 is included in the header of the packet transferred from the subscriber terminal device 3 ₁ α temporarily, buffer 11
To 13 corresponding buffers. For example, assume that buffer 11 is the buffer. In the buffer 11, other packets β, γ, and δ that share a route partway are also stored. When four or more packets are stored in the buffer 11, the header reediting unit 14 outputs the bit rate of 600 Mb / m of the line accommodated in the regional network 4-21 from the buffer 11.
Four packets α, β, γ, and δ are read so as to conform to S. At this time, if the four packets α, β, γ, and δ are referred to as a packet group, the header reediting unit 14 is common to each of the packets α, β, γ, and δ constituting the packet group. New route information “F” is created and added to the first packet of this packet group. The packets are transferred from the subscriber network 4-11 local networks 4-21 via the multiplexing circuit 20 of the speed converting unit 5 _11. At this time, in some cases, the vehicle may be piggybacked on a packet of another connection.

The packet shown in FIG. 3A is 53 bytes, and the packet group shown in FIG.
=) 212 bytes plus 5 bytes as a new header, which is 217 bytes. Although the time length of 5 bytes differs between the packet of the subscriber network 4-11 and the packet group of the regional network 4-21, the time length of 5 bytes is treated as a negligible time length here.

That is, the essence of the present invention resides in that a fixed length packet having an optimum bit length is used in each communication network having a different bit rate, and there is no reason to strictly define the coincidence of the time length of the packet and the packet group. . Of course, if the time lengths are the same, it is advantageous because the header processing device of the same specification can be used in each communication network, but there is no need to prepare a high-speed header processing device even if it does not have the same specification. Have the effect of the present invention. Here, the description has been made assuming that the time length of 5 bytes of the newly added header is different between the packet and the packet group, but the effect of the present invention can be obtained even if there is a larger time length difference. The difference may range, for example, from 1/3 to 3 times between two communication networks having different bit rates.

In the 2.4 Gb / S relay network 4-3, 53
In a byte packet, as shown in FIG.
Contiguous packets can be used. That is, 5 bytes are added as a new header to 848 bytes, resulting in 853 bytes. The 16 consecutive packets will be referred to as a packet sequence. The speed converting unit 5 ₂₁ of local networks 4-21, temporarily packet groups according to route information "F" to distribution circuit 10 is included in the packet group header transferred from local networks 4-21 buffer 11
13 in the corresponding buffer. For example, assume that buffer 11 is the buffer. In the buffer 11,
Packets that have been distributed halfway from other packet groups sharing the same route are also stored. When 16 or more packets are stored in the buffer 11, the header reediting unit 14 converts the 16 packets from the buffer 11 so as to conform to the bit rate of 2.4 Gb / S of the line accommodated in the relay network 4-3. Read. The header reediting unit 14 creates new route information “B” common to each packet constituting the packet sequence, and adds it to the first packet of the packet sequence. The packet sequence is transferred to the relay network 4-3 via the multiplexing circuit 20 of the speed converting unit 5 _21. At this time, in some cases, the vehicle may be piggybacked on a packet of another connection.

The packet shown in FIG. 3A is 53 bytes, and the packet sequence shown in FIG.
=) 848 bytes plus 5 bytes as a new header, resulting in 853 bytes. Although the time length of the packet of the subscriber network 4-11 differs from that of the packet sequence of the relay network 4-3 by 5 bytes, the packet length is treated as an ignorable range here.

That is, the essence of the present invention resides in that a fixed length packet having an optimum bit length is used in each communication network having a different bit rate, and there is no reason to strictly define the coincidence of the time lengths of the packet and the packet sequence. . Of course, if the time lengths are the same, it is advantageous because the header processing device of the same specification can be used in each communication network, but there is no need to prepare a high-speed header processing device even if it does not have the same specification. Have the effect of the present invention. Here, the description has been made assuming that the time length of 5 bytes of the newly added header is different between the packet and the packet sequence, but the effect of the present invention can be obtained even if there is a larger time length difference. The difference may range, for example, from 1/3 to 3 times between two communication networks having different bit rates.

[0037] In the speed conversion section 5 ₂₂ of local networks 4-22, the packet sequence according to route information "B" to the distribution circuit 10 is included in the header of the packet sequence transferred from the relay network 4-3 temporarily The data is accumulated in the corresponding buffer among the buffers 11 to 13. For example, assume that buffer 11 is the buffer. The buffer 11 also stores packets that have been distributed from other packet trains having a common route halfway. When a large number of packets are accumulated in the buffer 11,
The header reediting unit 14 reads out four packets at a time so as to conform to the bit rate of 600 Mb / S of the line accommodated in the regional network 4-22 and forms a packet group. Further, the header reediting unit 14 creates new route information “C” common to each packet constituting the packet group, and adds it to the first packet of the packet group. The packets are forwarded to the subscriber network 4-14 via the multiplexing circuit 20 of the speed conversion section 5 _22. At this time, in some cases, the vehicle may be piggybacked on a packet of another connection.

[0038] In the speed conversion section 5 ₁₄ of the subscriber network 4-14,
The distribution circuit 10 temporarily stores the packet group in the corresponding buffer among the buffers 11 to 13 according to the route information “C” included in the header of the packet group transferred from the local network 4-22. For example, assume that buffer 11 is the buffer. In the buffer 11, packets distributed from other packet groups sharing a common route halfway are also stored. When the packets are stored in the buffer 11, the header reediting unit 14 reads out the packets one by one so as to conform to the bit rate of 150 Mb / S of the line accommodated in the subscriber network 4-14. Header of this time packet has a header added by the subscriber terminal unit 3 ₁ (route information "G"), is transferred to the subscriber terminal device 3 ₂ via the multiplexing circuit 20.

(Summary of Embodiment) When a composite packet is created, there are a system in which a 53-byte packet is directly inserted into a payload and a system in which an identifier is used. In the present invention, any system may be used.

Assuming that there are only a certain number of subscriber terminal devices that actually make calls and that the line concentration is about 10: 1, when 6560 terminals are located in Japan, the regional networks 4-21 and 4-22
There are only 164 routes in the above and 16 routes in the relay network 4-3. In other words, the conventional transit exchange is 6
The packet-by-packet routing was performed while identifying the VCI / VPI of 560. However, it is enough to composite about 16 packets and regard them as one packet. It turns out there is.

FIG. 4 shows an example of switching from a 150 Mb / S exchange to 600
This is a configuration for accessing an Mb / S line. Reference numeral 5 denotes a speed conversion unit. FIG. 2 is an enlarged view of a portion 5 in which the packets for each route are temporarily stored and
If more than one packet is accumulated or a time-out occurs, 600 μb / S of 2.7 μS time, that is, 2
Make a packet of 07 bytes + 5 bytes, 600Mb /
Transfer on the S transmission path. This route corresponds to a route uniquely given on the area networks 4-21 and 4-22.

FIG. 5 shows the operation of the switch of 600 Mb / S. The routing is performed only with the information of the header without being aware of the content of 212 bytes at all.

However, here, the fixed time length is 2.7 μS
Although the header is described as having 5 bytes, the fixed time does not necessarily have to be strict, and a packet having a fixed time length at each transmission rate may be used. For example, 150 Mb
/ S can be 2.7 μS and 600 Mb / S can be 2 μS. Also, the header does not need to be 5 bytes at all,
It suffices if information such as routing can be transferred. As described above, the 53-byte packet in the payload within 2.7 μS only needs to be able to identify each packet.
It is conceivable to transfer the data by byte + α or the like. Also, CB
For R (Constant Bit Rate) data and the like, identification by time position is also possible at a fixed 48 bytes.

[0044]

As described above, according to the present invention,
It is possible to reduce the header processing speed of a packet in a high-speed switch. Therefore, the installation cost of the communication network can be reduced. Further, the throughput of the communication network can be improved.

[Brief description of the drawings]

FIG. 1 is a diagram showing a communication network configured in multiple stages.

FIG. 2 is a block diagram of a speed conversion unit.

FIG. 3 is a diagram showing a format of a packet.

FIG. 4 is a diagram showing a configuration when a 150 Mb / S exchange accesses a 600 Mb / S line.

FIG. 5 illustrates an operation of a 600 Mb / S switch.

FIG. 6 is a diagram showing a conventional ATM exchange.

[Explanation of symbols]

1 exchange 3 _1, 3 ₂ subscriber terminal 4-11～4-14 subscriber network 4-21,4-22 local networks 4-3 relay network 5,5 _{11-5 14,} 5 _{21-5 23} speed conversion Unit 10 distribution circuit 11-13 buffer 14-16 header reediting unit 20 multiplexing circuit α, β, γ, δ packet

Claims (3)

[Claims] 1. A first communication network having a bit rate of r ₁ b / S, a plurality of the first communication networks, and a bit rate of r
Packet communication comprising a second communication network of ₂ b / S and a speed conversion means for mutually converting a bit rate of a packet passing between the first communication network and the second communication network. In the network, the speed conversion unit may be configured such that a packet length of the first communication network and a packet length of the second communication network are each a fixed length, and one packet time is substantially equal between the two communication networks. A packet communication network comprising means for setting a bit length of a packet so that the packet length is as follows. 2. The packet according to claim 1, wherein one packet of the second communication network includes n packets (n = r ₂ / r ₁ ) of the first communication network and a newly added header. Communication network. 3. The speed conversion unit according to claim 1, further comprising: a unit for distributing the packet according to a header content of the packet arriving from the first communication network, and a buffer provided for each route. 13), when a number of packets conforming to the bit rate of the destination communication network are stored in the buffer, the plurality of packets are sequentially read out from the buffer, and a common route of the plurality of packets is stored in the first packet. 3. The packet communication network according to claim 2, further comprising a header reediting unit (14 to 16) for adding a new header to represent.