Optical communications – Multiplex – Hybrid
Reexamination Certificate
1999-02-22
2004-05-04
Pascal, Leslie (Department: 2633)
Optical communications
Multiplex
Hybrid
C398S098000, C370S539000, C370S541000, C370S466000, C370S395520
Reexamination Certificate
active
06731876
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention generally relates to a packet transmission device and a packet transmission system each of which realizes communication by exchanging packets as basic units of the communication, and, more particularly, to a packet transmission device and a packet transmission system each of which uses IP packets, which are used in communication by using the Internet Protocol (IP). The packet transmission device and the packet transmission system are applicable to an IP network, and are used to connect IP routers located in different places.
2. Description of the Related Art
Recently, WDM (Wavelength Division Multiplexing) transmission technologies are becoming widely available for the purpose of heavily increasing network capacity. In addition, the WDM transmission technologies are becoming available for transmitting IP packets. Conventionally, in order to transmit an IP packet by using the WDM transmission technologies, it is required to map the IP packet into an SDH (Synchronous Digital Hierarchy) path first, and then a SDH path signal needs to be transmitted by a WDM transmission signal. Therefore, in order to transmit an IP packet by using the WDM transmission technologies, as shown in
FIG. 18
, packet transmission devices
1
,
3
,
5
and SDH transmission devices
7
,
9
are necessary.
As to other methods for transmitting the IP packet, an ISDN (Integrated Services Digital Network) and a leased line are widely used. For realizing a high-capacity transmission of the IP packet, an IP packet transmission device which implements a technology called IP-over-SDH, in which technology the IP packet is mapped into an SDH path payload area, is utilized. The IP-over-SDH technologies are completely described in the RFC1619 by the IETF.
In the following, an overview of the IP-over-SDH technologies will be described with reference to
FIG. 19
to FIG.
21
.
As shown in
FIG. 19
, IP routers which are located in different places are connected via an SDH transmission network. In the network, IP packets which are assembled in a destination batch are accommodated in an SDH path payload area and an SDH path signal is transmitted. For example, SDH paths are established between an IP router
1201
and each of IP routers
1202
-
1204
.
An SDH signal, which is configured by multiplexing a plurality of SDH path signals, is transmitted over a transmission line from an IP router, and routed in a batch of the SDH path signals at SDH cross-connect devices, and then transmitted to its destination. 7 types of SDH path signals are defined as VC-
11
, VC-
12
, VC-
2
, VC-
3
, VC-
4
, VC-
4
-
4
c
and VC-
4
-
16
c
(VC is an acronym for Virtual Container). The capacities of the types are 1.6 Mb/s, 2.2 Mb/s, 6.8 Mb/s, 49 Mb/s, 150 Mb/s, 599 Mb/s and 2396 Mb/s respectively. Therefore, if a high-capacity is required between endpoints, VC-
3
, VC-
4
, VC-
4
-
4
c
or VC-
4
-
16
c
may be used.
An IP router which implements conventional IP-over-SDH technologies generally has a part which processes routing and an interface part for interfacing between the IP router and an outgoing line. The interface part converts IP data into SDH data and converts SDH data into IP data.
A configuration of an IP/STM converter in the interface part will be described with reference to
FIG. 20
(STM is an acronym for Synchronous Transport Module). IP packets divided into 3 groups by destinations are entered into IP/VC converters
1331
-
1333
through IP packet input lines
1301
-
1303
. In the IP/VC converter
1331
, first, IP packets are accommodated in an SDH path payload, and second, overhead data entered through an SDH path overhead data input line
1341
and other overhead data generated in the IP/VC converter
1331
are added to the SDH path payload, and, as a result, an SDH path signal, which is called a Virtual Container (VC) signal, is formed and output over an output line
1351
. VC signals from the IP/VC converters
1331
-
1333
are accommodated into an SDH section payload after being multiplexed by a VC multiplexing circuit
1322
. An STM signal is formed by adding overhead data to the SDH section payload in an SDH section overhead inserting circuit
1323
, and the STM signal is sent out over the line
1311
.
In an STM/IP converter, as shown in
FIG. 21
, first, each VC signal is extracted from an STM signal in an STM/VC converter
1421
, and second, IP packets are extracted from SDH path payloads in VC/IP converters
1431
-
1433
. Then the IP packets are sent to the inside of the IP router (
1411
-
13
).
As another technology in which packets are accommodated into an SDH section payload area, the international publication W094/03004 (PCT/EP93/01675) “Local or/and Transit Exchange for a Broadband Communication Network” discloses technologies in which a packet of fixed length (normally called an ATM cell) which is used in an ATM (asynchronous transfer mode) network is accommodated into an SDH section payload area. According to the technologies, the ATM cell is accommodated into the SDH section payload area by way of a VC signal.
However, the above conventional technologies have the following disadvantages. First, in the above conventional WDM technology, because the IP packets should be transmitted via the SDH path, overhead data of the SDH path signal should be transmitted also. Therefore, the transmission capacity of an optical path cannot be fully used, and expensive devices for performing the SDH path transmission are necessary.
Second, in the above conventional IP-over-SDH technology, because the IP packets are transmitted over the SDH path signal, there is an advantage that an IP packet transmission device can transmit the IP packets to a plurality of destinations by connecting one transmission line to the IP packet transmission device. From the viewpoint of the transmission capacity, however, because a part of the transmission capacity is consumed by transmission of the SDH path overhead, the transmission capacity of the transmission line cannot be fully used. Therefore, some problems such as a cost increase of the transmission line may arise for realizing high-capacity communication which is required recently. Further, when the destination of the IP packets is limited to only one, because it is not necessary to have SDH paths, the SDH path overhead area is not used, and, as a result, the overhead part of the transmission capacity is wasted. Further, because an SDH cross-connect system which handles VC-
4
-
4
c
and/or VC-
4
-
16
c
is not yet in actual use, it is necessary to establish a plurality of SDH paths between the same endpoints for realizing a high-capacity communication beyond VC-
4
(150 Mb/s).
Third, according to the technologies disclosed in the international publication WO94/03004 (PCT/EP93/01675), packets are accommodated into the SDH section payload area by way of VC signal. Therefore, the SDH section payload area should have information used only for handling the VC signal, so a part of the transmission capacity is wasted as in the case mentioned above.
SUMMARY OF THE INVENTION
It is a general object of the present invention to provide a packet transmission device and a packet transmission system which can realize high-capacity communication by transmitting packets over a wavelength division multiplexing (WDM) link without any SDH path. It is another object of the present invention to provide a packet transmission device and a packet transmission system which can realize high-capacity communication by eliminating waste of the SDH path overhead area in the case of SDH transmission. It is more specific object of the present invention to provide a packet transmission device and a packet transmission system which is applicable to an IP network.
The above objects of the present invention are achieved by a circuit for converting packets into an optical path signal, wherein the circuit is used in a transmission device for transmitting packets, the circuit including:
a part for converting the packets into a plurality of data streams:
a part
Okamoto Satoru
Sato Ken'ichi
Kenyon & Kenyon
Nippon Telegraph and Telephone Corporation
Singh Dalzid
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