The present invention generally relates, in a first aspect, to a multilayer communications network system for distributing multicast services, combining a switched optical transport network layer, such as a WSON, and an electronic packet switched network layer, such as an IP/MPLS, and more particularly to a system where the electronic network is used for restoring connections lost due to failures in the optical network.
A second aspect of the invention relates to a method for distributing multicast services through a multilayer communications network system, which can be implemented by the system of the first aspect.
The invention provides a new restoration scheme for high capacity multicast services (e.g. HD-TV and UHDTV) over long-haul networks.
Wavelength division multiplexing (WDM) is one technology that is envisioned to increase bandwidth capability and enable bidirectional communications in optical networks. In WDM networks, multiple data signals can be transmitted simultaneously between network elements (NEs) using a single fibre. Specifically, the individual signals may be assigned different transmission wavelengths so that they do not interfere or collide with each other. The path that the signal takes through the network is referred to as the lightpath. One type of WDM network, a wavelength switched optical network (WSON) [6], seeks to switch the optical signals by means of ROADM (Reconfigurable Optical Add Drop Multiplexer) without optical-electrical-optical (OEO) conversions. ROADMs are asymmetric wavelength selective switching elements featuring ingress and egress line side ports as well as add/drop side ports.
ROADMs with drop & continue capability can provide one-to-many fan-out of a channel for optical multicasting so that a single optical channel (lambda) could be used for a point to multipoint (P2MP) connection.
Currently, there already exist technical alternatives for optical multicasting over WSON, such a those incorporating multicast resilience mechanisms for optical switching networks, as is the case of the disclosures of U.S. Pat. No. 7,366,417, which describes delivering multicast services on a wavelength division multiplexed network using a configurable four-port wavelength selective crossbar switch, and U.S. Pat. No. 6,850,707 referring to a secure optical layer multicasting to effect survivability.
Said technical alternatives, or current solutions, are based on two different approaches: protection and restoration.
As far as protection is concerned, it consists in pre-calculating a working multicast tree and a backup multicast tree, both according to shortest path algorithm. There is another condition to compute the backup tree: it must be link-disjointed respect to the working one (
At the initial situation, a pre-calculated working multicast tree is established (
As far as restoration is concerned, as soon as the network starts to work, a multicast tree is computed and established according to a given algorithm. After a multiple link failure event, if there is an error affecting any link of the established multicast tree, the resilience mechanism searches another possible multicast tree according to the available network resources, avoiding the broken links. In this manner, it is tried to maintain the multicast tree in all the access nodes.
Protection mechanisms are not able to restore multiple simultaneous link failures and consume dedicated WSON back up resources that cannot be used for other purposes. Furthermore, it requires completely disjoint working and backup multicasting trees and this might not be possible in some WSON networks.
Above problems might be solved by using dynamic restoration schemes. However, restoration mechanisms present another problem: recovery speed in WSON is very slow since the establishment of a new channel over the WSON requires some network reconfigurations (power channels equalization, filters tuning, etc.) which could take seconds or even minutes.
In this structure, the traffic (the data) is routed thanks to inter-domain routing protocols and other techniques to make the switching more efficient (such as MPLS [15]): traffic coming from the edges of the IP network (interconnection or access nodes) crosses the IP network through the transit nodes to reach the other edges (interconnection or access nodes).
As described in [16], IP/MPLS networks are able to support and restore multicast connections.
Some multicast resilience mechanisms for packet electronic switching networks are described in next patent documents: U.S. Pat. No. 7,251,214, regarding a system and method for providing protection of data communications in packet-based networks, U.S. Pat. No. 7,675,870 related to a IP-TV broadcasting service system and method using physical layer's multicast switch, U.S. Pat. No. 7,830,785 disclosing a system and method for restoration in a multimedia IP network and US2009245248 describes a method and apparatus for providing resiliency in multicast networks.
Electronic packet switching technologies (e.g. IP/MPLS) require complex and intensive power consumption techniques (e.g. optoelectronic conversions, packet by packet processing, etc.) that present important inefficiency problems for high traffic volumes [14]. Therefore, electronic switching technologies consume much more power and network resources (i.e. ports, chassis, footprint, etc.) than optical switching technologies for high capacity traffic flows such as the ones generated by HDTV or UHDTV applications.
All above existing patent documents, both the ones regarding optical switching networks and the ones related to packet electronic switching networks, are exclusively focused on a given technology (i.e. electronic packet switching or optical switching), nor proposing to combine both kind of networks.
Such a combination is disclosed in U.S. Pat. No. 7,269,185, regarding a management and control of multilayer networks, and addressing multilayer coordination, including WSON and IP/MPLS network layers, even for distributing multicast services. However, said patent does not disclose, not even suggests, providing a multilayer restoration mechanism for multicast services, the several layers described not being arranged nor used for such a restoration purpose.
The present inventors don't know any proposal specifying any multilayer restoration mechanism for multicast services.
It appears necessary to offer an alternative to the state of the art which covers the gaps found therein, particularly providing a solution to the problems referring to, on one hand, the slow recovery speed of optical networks and, on the other hand, the inefficiency problems for high traffic volumes of electronic switching networks.
To that end, the present invention provides, in a first aspect, a multilayer communications network for distributing multicast services, comprising at least a switched optical transport network layer, such as a Wavelength Switched Optical Network (WSON), and an electronic packet switched network layer, such as an Internet Protocol (IP) layer and/or a Multi Protocol Label Switching layer (MPLS), e.g. a IP/MPLS network layer.
On contrary to the proposal of U.S. Pat. No. 7,269,185, in the system of the first aspect of the invention, in a characteristic manner, the switched optical transport network layer transports multicast flows services and the electronic packet switched network layer is a backup layer of a dynamic restoration mechanism for recovery against one or more failures occurring in the switched optical transport network layer.
The switched optical transport network layer implements, for an embodiment, a network providing point to multipoint connections, or P2MP, said dynamic restoration mechanism being intended for the dynamic restoration of multiple failures in said point to multipoint connections.
According to an embodiment of the system of the first aspect of the invention, the switched optical transport network implements an optical multicast tree for distributing multicast flows there through, the multilayer communications network comprising a control plane module for computing a new multicast tree over the electronic packet switched network layer between a source node and destination nodes affected by a failure in the switched optical transport network, according to the available resources in the electronic packet switched network layer after the failure.
Other embodiments of the system of the first aspect of the invention are described in claims 6 to 13, and in a subsequent section.
A second aspect of the invention relates to a method for distributing multicast services through a multilayer communications network, where said multilayer communications network comprises at least a switched optical transport network layer and an electronic packet switched network layer.
On contrary to known proposals, the method of the second aspect of the invention comprises, in a characteristic manner, transporting multicast flows services through the switched optical transport network layer, and also comprises performing a recovery against one or more failures occurring in the switched optical transport network layer by means of a dynamic restoring carried out by using the electronic packet switched network layer as a backup layer.
For an embodiment, the method comprises:
According to an embodiment, the method comprises deleting the new multicast tree once the at least one failure has been repaired.
The method of the second aspect of the invention comprises, as per an embodiment, dynamically establishing over the electronic packet switched network layer the new multicast tree by means of multicast signalling.
For an embodiment of the method of the second aspect of the invention, and of a procedure of using the system of the first aspect, next actions are performed:
The present invention thus relies on an innovative combination of multilayer and multicast restoration schemes in order to optimize power and network resources consumption and enhance survivability for high capacity multicast services, such as HDTV and UHDTV, providing a resilience scheme after a link cut.
The invention aims to solve the efficiency problems of packet electronic switching techniques in terms of power and network resources consumption by using optical multicasting over WSON as default transport technology for high capacity traffic flows such as HDTV or UHDTV. On the other hand, optical multicasting problems in terms of low recovery speed or survivability against multiple failures are solved by using dynamic restoration mechanisms at an electronic packet layer.
Therefore, the invention combines optical multicasting over, for example, WSON and dynamic P2MP restoration over electronic packet switching (e.g. IP/MPLS) in order to maximize multicast service availability while minimizing their related power and network resources consumption.
The proposed invention combines the advantages of electronic (e.g. IP/MLPS) and optical switching (e.g. WSON) in order to minimize the network costs while maximizing the service survivability. As the optical switching is used by default, power and network resources consumption are low. Electronic switching is exclusively used as back up layer in order to assure fast recovery against one or more failures in the optical layer. Moreover, the survivability against multiple failures is high despite using the optical switching by default, because the service restoration after one or multiple failures is performed over a back up electronic packet switching network.
The previous and other advantages and features will be more fully understood from the following detailed description of embodiments, with reference to the attached drawings (some of which have already been described in the Prior State of the Art section), which must be considered in an illustrative and non-limiting manner, in which:
As it is shown in
The transmission module receives digital signal from the source node (e.g IP-TV Head End) by the INPUT PORT and either distributes it by the OUTPUT PORT1 towards an IP/MPLS router or by the OUTPUT PORT2 towards a WSON node, according to the information received from the CONTROL PORT. The optical signal distributed by OUTPOUT PORT2 is sent to a WSON node.
As highlighted in
In particular the Ct messages are received over the CONTROL PORT are the following:
This interface Ct allows the MRM to dynamically select the appropriate distribution layer for a multicast flow.
As shown in
Cr is the interface between the Transmission Module and the Multilayer Restoration Module (MRM). This interface allows the Reception Module to inform the MRM about Loss of Signal and Signal Recovery in the WSON. The following messages are sent over this interface:
Ci is the internal interface between the Power Detection Module and the Ethernet Switch. This interface allows the Power Detection Module to activate or deactivate the Ethernet switch input port connected to the optical transponder. The following messages are sent over this interface:
The Multilayer Restoration Manager (
Next, two procedures are described referring to both, embodiments of the method of the second aspect of the invention, and also as describing the actions to perform, for some embodiments, by the different elements of the system of the first aspect of the invention.
Procedure after a Failure in the WSON:
The information distributed over the Cr interface (SR_notification) allows the MRM to be informed about the Local Nodes being affected by a failure in the WSON.
After receiving the failure notification, the MRM request IP/MPLS network status information over the Cc interface between the MRM and the management/monitoring system of the IP/MPLS network. This interface allows the MRM to receive IP/MPLS network status information and send multicast connections request. The following messages are exchanged over this interface:
Once the optimum multicast tree is computed the MRM could trigger the multicast tree set up by exchanging the following messages over the Cs interface between the MRM and the IP/MPLS nodes.
Once the IP/MPLS multicast tree is available the MRM sends an IP_P2MP_request to the Transmission Module over the Ct interface in order to send the HD-TV traffic over the IP/MPLS network. This message is sent after receiving a P2MP_Setup_response message from the Cs interface.
Procedure after a Service Recovery in the WSON
The information distributed over the Cr interface (SR_notification) allows the MRM to be informed about the service recovery in the WSON.
After receiving the failure notification, the MRM request the IP/MPLS multicast connection tear down by exchanging the following messages over the CS interface:
Once the IP/MPLS multicast tree is removed the MRM sends an IP_P2MP_remove message to the Transmission Module over the Ct interface in order to remove the multicast traffic from the IP/MPLS network. This message is sent after receiving a Remove_P2MP_response message from the Cs interface.
A potential use case of the proposed invention could be IPTV distribution and restoration in IP/MLPS over WSON core networks. IP-TV is digital television delivered through high speed internet connection. In this service, channels are encoded in IP format and delivered to the TV through an operator's transport network. As shown in
IP-TV traffic volume over long haul networks does not depend on the number of customers but on the number, definition and codification of TV channels. A potential service including 100 HDTV channels, 10 3D TV channels and 10 UHDTV channels would need 6 Gbps from the TV Head-End to the rest of Service PoPs in the metro area.
The proposed invention could be applied in Long-Haul Transport Networks
A digital IP-TV stream at 6 Gbps including all TV channels is sent over an optical carrier (λTV) by the transmission module. This optical carrier is optically distributed by the WSON up to all destination nodes where the reception module converts the optical signals into the original IP-TV stream generated by the Head End. As shown in
In
A person skilled in the art could introduce changes and modifications in the embodiments described without departing from the scope of the invention as it is defined in the attached claims.
ASE AMPLIFIED SPONTANEOUS EMISSIONS
CSNRZ CARRIER-SUPPRESSED NON RETURN-TO-ZERO (CSNRZ)
DPSK DIFFERENTIAL PHASE SHIFT KEYING
IP INTERNET PROTOCOL
IPTV INTERNET PROTOCOL TELEVISION (IP-TV)
MPLS MULTI PROTOCOL LABEL SWITCHING
OSNR OPTICAL SIGNAL TO NOISE RATIO
ROADM RECONFIGURABLE OPTICAL ADD DROP MULTIPLEXER
UHDTV ULTRA HIGH DEFINITION TV
WSON WAVELENGTH SWITCHED OPTICAL NETWORKS
Number | Date | Country | Kind |
---|---|---|---|
P201130032 | Jan 2011 | ES | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2011/074081 | 12/27/2011 | WO | 00 | 9/30/2013 |