Error detection/correction and fault detection/recovery – Data processing system error or fault handling – Reliability and availability
Reexamination Certificate
2002-12-27
2004-08-24
Baderman, Scott (Department: 2184)
Error detection/correction and fault detection/recovery
Data processing system error or fault handling
Reliability and availability
C714S748000
Reexamination Certificate
active
06782490
ABSTRACT:
BACKGROUND OF THE INVENTION
IP multicasting provides an efficient way for a source to send a stream of User Datagram Protocol (UDP) packets to a set of recipients. The source sends only one copy of each packet to an IP network, such as the Internet, for example. The routers in the IP network do the work required to deliver that packet to each recipient. Various IP multicast routing protocols can be used in an IP network. These allow the routers to communicate with each other so that the multicast datagrams are sent only to those subnetworks with receivers that have joined a multicast session.
A multicast session is identified by an IP address and port number. The IP address is a Class D address in the range from 224.0.0.0 to 239.255.255.255. IP multicasting is more efficient than unicasting for group communication. Unicasting requires that the source send a separate copy of each datagram to each recipient. This requires extra resources at the source and in the IP network and is wasteful of network bandwidth.
Some useful background references describing IP multicasting in greater detail include: (1) Kosiur, D., “IP Multicasting: The Complete Guide to Corporate Networks”, Wiley, 1998; (2) Maufer, T., “Deploying IP Multicast in the Enterprise”, Prentice-Hall, 1997; (3) Deering, S., “Host Extensions for IP Multicasting,” Network Working Group Request for Comments Internet RFC-1112, August 1989; (4) Waitzman, D., Partridge, C., Deering, S., “Distance Vector Multicasting Routing Protocol,” Network Working Group Request for Comments Internet RFC-1075, November 1988; (5) Schulzrinne, H., Casner, S., Frederick, R., Jacobson, V., “RTP: A Transport Protocol for Real-Time Applications,” Network Working Group Request for Comments Internet RFC 1889, Jul. 18, 1994. The IP multicast protocol set forth in the IETF RFC 1112 “Host Extensions for IP Multicasting” is the standard protocol for enabling hosts to establish and conduct IP multicast sessions on the Internet. The IETF RFC 1075, “Distance Vector Multicast Routing Protocol (DVMRP),” describes a protocol for propagating routing information among multicast-enabled routers.
The multicast backbone on the Internet (Mbone) is an extension of the Internet backbone to support IP multicasting. The Mbone is formed collectively by the portion of the network routers in the Internet backbone that are programmed to perform the IP multicast routing protocol. Those routers in the Internet backbone that are programmed to handle IP multicast sessions, as well as unicast sessions, are referred to herein as multicast-enabled routers. The Mbone is a virtual network that is layered on top of sections of the physical Internet. It is composed of islands of multicast-enabled routers connected to each other by virtual point-to-point links called “tunnels.” The tunnels allow multicast traffic to pass through the non-multicast-enabled routers of the Internet. IP multicast packets are encapsulated as IP-over-IP, so that they look like normal unicast packets to the intervening routers. The encapsulation is added upon entry to a tunnel and removed upon exit from a tunnel. This set of multicast-enabled routers, their directly connected subnetworks, and the interconnecting tunnels define the Mbone. For additional details, see (1) Comer, Douglas E. Intemetworking with TCP/IP: Volume 1-Principles, Protocols, and Architecture, Third Edition. Englewood Cliffs, N.J.: Prentice Hall, 1995; (2) Finlayson, Ross, “The UDP Multicast Tunneling Protocol”, IETF Network Working Group Internet-Draft, published Sep. 9, 1998, http://search.ietf.org/internet-drafts/draft-finlayson-umtp-03.txt; and (3) Eriksson, Hans, “MBone: The Multicast Backbone,” Communications of the ACM, August 1994, Vol.37, pp.54-60.
Since the multicast-enabled routers of the Mbone and the non-multicast-enabled routers of the Internet backbone have different topologies, multicast-enabled routers execute a separate routing protocol to decide how to forward multicast packets. The majority of the Mbone routers use the Distance Vector Multicast Routing Protocol (DVMRP), although some portions of the Mbone execute either Multicast OSPF (MOSPF) or the Protocol-Independent Multicast (PIM) routing protocols. For more details about PIM, see: Deering, S., Estrin, D., Farrinaci, D., Jacobson, V., Liu, C., Wei, L., “Protocol Independent Multicasting (PIM): Protocol Specification”, IETF Network Working Group Internet Draft, January, 1995.
Multicasting on the Internet has a unique loss environment. On a particular path the losses occur in bursts, as multicast-enabled routers become congested, rather than the losses having the characteristics associated with white noise. When packets are lost on a particular link in the multicast tree, any downstream receivers lose the same packet. Therefore, a large number of retransmissions may occur at the same time in response to negative acknowledgments from receivers. One problem is that such retransmissions are typically in multicast sessions which will tend to encounter the same congested nodes as did the original multicast sessions.
However, congestion in different parts of network is not correlated since traffic to receivers in other parts of the multicast tree does not necessarily pass through the same congested nodes and therefore does not lose the same bursts of packets. Therefore, path diversity would be a good means for recovering at least some of the missing packets, if there were a way to coordinate such a recovery.
Another problem in IP multicasting is that some Internet Service Providers (ISPs) discriminate against multicast packets and discard them before discarding the packets for other services. Therefore, it would be worthwhile balancing the efficiency of multicast transmissions with the quality of point-to-point transmissions.
What is needed is a way to improve the quality of audio and video multicasts of live conferences, news broadcasts and similar material from one source to many receivers over the Internet. Live audio and video material is not as interactive as a telephone conversation, for example, and therefore, a few seconds of delay can be tolerated to recover missing packets. What is needed is a way to recover as many packets as possible with a limited amount of work and delay, rather than to do whatever is necessary for a perfect recovery of all missing packets.
SUMMARY OF THE INVENTION
The invention is a system and method for the repair of IP multicast sessions. In one aspect of the invention a repair server polls multiple transmit servers to accumulate as many of the packets missing from the multicast session as possible. A network includes a source of multicast packets in a multicast session and a plurality of multicast recipients in that session. A repair server in the network provides the packets it receives to the recipients. The repair server includes a missing packet detector. There is a plurality of retransmit servers in the network buffering portions of the packets they respectively receive during the session. The repair server maintains an ordered list of the retransmit servers that are most likely to have buffered copies of packets missing from the session. When the repair server detects that there are packets missing from the session it has received, it uses the ordered list to sequentially request the missing packets from respective ones of the plurality of retransmit servers.
The ranking criteria that the repair server can apply to rank the respective retransmit servers in its ordered list can be based on the performance of the retransmit servers in past repair sessions. Alternately, the ranking criteria can be based on receiver reports multicast by each of the retransmit servers. For example, multicast receiver reports from the retransmit servers include the fraction of data packets from the source lost by a retransmit server, the cumulative number of packets from the source that have been lost by a retransmit server, an estimate of the statistical variance of the packet interarrival time experienced by a retransmit server, and the round trip propa
Maxemchuk Nicholas Frank
McManamon David
Shur David Hilton
Zelezniak Aleksandr
AT&T Corp.
Baderman Scott
Michael Haynes PLC
LandOfFree
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