Optical communications – Multiplex – Wavelength division or frequency division
Reexamination Certificate
2000-12-06
2004-05-25
Negash, Kinfe-Michael (Department: 2633)
Optical communications
Multiplex
Wavelength division or frequency division
C398S050000, C398S091000, C398S154000, C370S503000, C370S907000, C375S356000
Reexamination Certificate
active
06741812
ABSTRACT:
This invention relates to a synchronous digital communications system as set forth in the preamble of claim 1 and to a method of optically transmitting electric signals as set forth in the preamble of claim 6.
A synchronous digital communications system is based, for example, on a standard for synchronous digital hierarchy (SDH/SONET standard). In such a digital communications system, individual network elements are interconnected by different transmission media (e.g., copper cables, optical fiber waveguides, or radio links). A network element is, for example, an exchange for a public switched telephone network, a cross-connect, or an add/drop multiplexer. To synchronize the network elements, two techniques are known: master-slave synchronization and mutual synchronization.
The master-slave technique, also referred to as hierarchical synchronization, uses a unique primary reference clock for synchronization of a first hierarchical level of network elements, also referred to as nodes. These nodes give their derived clocks to the next level nodes, and so on. In the mutual synchronization technique, all nodes are at a peer level interconnected by the existing digital links. Each node calculates a mean phase value of the incoming clock signals and its own internal clock.
From DE 44 46 511 it is known to avoid timing loops by grouping interface units of each network element that are used for synchronization in two classes, thereby defining a synchronization hierarchy. The interface units of one of the classes ignore received synchronization signals, and the interface units of the other class transmit synchronization signals (clock references).
Network elements have a number of interface units, which generally all serve to receive and transmit information signals, i.e., speech, data. Some predefined interface units additionally serve to receive and/or transmit synchronization signals. All-electric synchronous digital communications systems have nonswitched physical connections. A synchronization hierarchy is defined by predetermined paths. If section-by-section radio or point-to-point optical transmission is used, the electric signals (information+synchronization) are switched through transparently. In this way, the network element interface units used for synchronization always receive the necessary synchronization signals. Even if no information is transmitted in the meantime, the connections between the network elements are maintained, for example by transmitting default messages, so that continuous synchronization is ensured.
A new situation arises if during section-by-section optical transmission, no time-invariable through-switching takes place. Then, optical connections are no longer permanently assigned to wavelengths. A flexible and time-variable assignment of optical channels to wavelengths is possible. For example, an optical channel for transmitting a first message packet is implemented by a first switched optical connection using a first wavelength, and an optical channel for transmitting a second message packet is implemented by a second switched optical connection using a second wavelength. If network elements with switching properties, such as optical cross-connects, are used in conjunction with wavelength-division multiplexing, arbitrary, time-variable optical channels can be created for transmitting information signals, such as SDH or SONET signals. For example, a first optical connection for creating a first optical channel is used in a first time period to transmit messages from a first network element to a second network element, with an optical cross-connect interposed between the network elements. The first optical connection is implemented using a first wavelength, for example. Via the interface unit assigned to the first wavelength, the second network element synchronizes itself, i.e., the sychronization clock, which corresponds to a bit-rate clock, is used for all interface units of the second network element. If in a second time period, the optical cross-connect uses the first wavelength for a second optical connection to create a second optical channel for transferring information from the first network element to a third network element, the connection to the second network element via the first wavelength is interrupted. The second network element can no longer synchronize itself in the second time period. Even if the second network element received information and/or synchronization signals over a second or third optical connection, it could not synchronize itself, because only the interface unit assigned to the first wavelength is reserved for the purpose of accomplishing synchronization for all interface units. Instead of using one interface unit, synchronization can also be achieved using two or three interface units, for example by means of an additional selection facility that selects the clock of the best quality. Through the use of three interface units for synchronization purposes in conjunction with three wavelengths, the probability that no synchronization is possible can be minimized but cannot be reduced to zero.
The invention proposes a synchronous digital communications system as set forth in claim 1 and a method of optically transmitting electric signals as set forth in claim 6.
The synchronous digital communications system according to the invention serves to transmit electric signals optically. The electric signals to be transmitted are converted from electrical to optical form and are then transmitted using wavelength-division multiplexing (WDM) or dense wavelength-division multiplexing (DWDM). A synchronization manager and a connection manager are provided. The synchronization manager is adapted to configure dedicated optical synchronization links. The connection manager is adapted to configure switched optical communication links from a pool of wavelengths taking account of the dedicated synchronization links only. This has the advantage that independently of the switched communication links, synchronization is constantly ensured throughout the system. Each network element has at least one interface unit that is reserved for synchronization and that constantly receives signals on the wavelength reserved for synchronization.
The synchronous digital communications system comprises, for example, at least three network elements interconnected by optical lines, each of the network elements comprising at least one electrical-to-optical converter and at least one optical-to-electrical converter. At least one optical cross-connect is connected between the network elements. Each optical cross-connect is adapted to use individual wavelengths for the switched transfer of signals from one network element to another. The cross-connect performs switching operations for communication links. With respect to the switching, however, the cross-connect is limited to those wavelengths which do not impair the established synchronization.
In a preferred embodiment, the synchronous digital communications system comprises at least three network elements designed as SDH or SONET elements that are interconnected by optical lines. Between the network elements, hierarchical synchronization or mutual synchronization is established by the synchronization manager. Prior to the switching of an optical communication link, the connection manager checks whether the established synchronization is impaired by the planned switching. If that is the case, the planned switching will not take place. An alternative link will be searched for. Only when a link that does not impair the established synchronization has been found will the switching take place. For instance, a reference clock generated in a first network element is transmitted for synchronization purposes to a second network element at a first wavelength. A clock derived from the received reference clock in the second network element is transmitted to a third network element at a second wavelength. Between the first and second network elements, the first wavelength is then reserved for the transfer of synchro
Alcatel
Negash Kinfe-Michael
Sughrue & Mion, PLLC
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