TY - GEN
T1 - Near optimal flow labeling in ATM/IP-LSR networks using multi-segment flows
AU - Harwood, Aaron
AU - Shen, Hong
PY - 2000
Y1 - 2000
N2 - Packet or datagram based routing is widely used for the Internet mainly due to its robustness, ease of implementation and autonomous behavior. Hierarchical networks are necessary to provide scalability. Previous developments proposed for ATM technology to be the basis of packet switched routing protocols. This technology provides flows to reduce the number of times a packet's destination address must be looked up in a routing table thereby increasing the performance of the overall system. Basic methods to establish and maintain these flows have emerged. Clearly one cannot define a flow between every (source, destination) pair since the number of destinations (in the Internet) is prohibitively large. We provide a definition of the problem with optimality criteria, and an algorithm that autonomously establishes a dynamic hierarchy of flows over an arbitrary network according to traffic demand. If the network is of size n, our algorithm uses only O(n0 logn0 n) labels at each router where n0 = e ≈ 3. Packets are routed over a λ-segmented flow such that the label table is accessed at most λ = logn0 n - 1 times. We show that the total table look-up complexity, O(n0 logn02 n), is a factor Θ(logn0 log n0 n) times the optimal, which makes substantial improvement of other results known to us. Our hierarchy of flows naturally exists transparently on top of the underlying hierarchical address space (IP) and requires no additional information.
AB - Packet or datagram based routing is widely used for the Internet mainly due to its robustness, ease of implementation and autonomous behavior. Hierarchical networks are necessary to provide scalability. Previous developments proposed for ATM technology to be the basis of packet switched routing protocols. This technology provides flows to reduce the number of times a packet's destination address must be looked up in a routing table thereby increasing the performance of the overall system. Basic methods to establish and maintain these flows have emerged. Clearly one cannot define a flow between every (source, destination) pair since the number of destinations (in the Internet) is prohibitively large. We provide a definition of the problem with optimality criteria, and an algorithm that autonomously establishes a dynamic hierarchy of flows over an arbitrary network according to traffic demand. If the network is of size n, our algorithm uses only O(n0 logn0 n) labels at each router where n0 = e ≈ 3. Packets are routed over a λ-segmented flow such that the label table is accessed at most λ = logn0 n - 1 times. We show that the total table look-up complexity, O(n0 logn02 n), is a factor Θ(logn0 log n0 n) times the optimal, which makes substantial improvement of other results known to us. Our hierarchy of flows naturally exists transparently on top of the underlying hierarchical address space (IP) and requires no additional information.
UR - http://www.scopus.com/inward/record.url?scp=84890358241&partnerID=8YFLogxK
U2 - 10.1109/ICON.2000.875796
DO - 10.1109/ICON.2000.875796
M3 - Conference contribution
AN - SCOPUS:84890358241
SN - 0769507778
SN - 9780769507774
T3 - IEEE International Conference on Networks, ICON
SP - 243
EP - 247
BT - Proceedings - IEEE International Conference on Networks 2000
T2 - 2000 IEEE International Conference on Networks: Networking Trends and Challenges in the New Millennium, ICON 2000
Y2 - 5 September 2000 through 8 September 2000
ER -