This invention relates to private network-to-network interfaces (PNNI), and more specifically to methods for constructing PNNI networks with optimized architecture.
Private network-to-network interfaces (PNNI) refers to very large ATM networks that communicate between multiple private networks. A typical PNNI network is organized in peer groups. These are subunits of the total network that are interconnected as a group, with each group then interconnected in the PNNI network. An advantage of this architecture is that communications between members in a peer group can be independent of overall network management. When a communication between a node in one peer group and a node in another peer group is initiated, the PNNI protocol is used for that call set-up and management. The size of the peer groups, i.e. the number of nodes in each peer group, also affects the overall performance of the PNNI network.
Depending on the number of nodes served by the PNNI network, the architecture may be flat (non-hierarchical) or may have two or more hierarchical levels. When the network topology moves to multiple level architecture, several new effects on network performance are introduced. A primary motive for introducing new levels in a PNNI network is to increase routing efficiency and reduce call set-up time. However, added levels increase cost and management complexity. Thus there is an important trade-off when considering adding new hierarchical levels. A technique for resolving this trade-off is described and claimed in my co-pending application Ser. No. 10/346,460.
In both flat and multi-level networks, the size of the peer groups, i.e. the number of nodes in each peer group, affects the overall performance of the PNNI network. Thus the division of the network nodes into peer groups presents an important design variable that has not been generically solved previously in a rigorous fashion.
According to the invention, a technique has been developed that evaluates important network performance parameters, for example, call set-up time, in terms of the peer group size. These are used to determine the optimum peer group size for a given PNNI network.
The invention may be better understood when considered in conjunction with the drawing in which:
The FIGURE is a schematic diagram of a PNNI network showing a sample peer group configuration.
With reference to
In the discussion that follows, let N be the total number of lowest-level nodes (i.e., the number of ATM switches). Let x1 be the number of lowest-level nodes in each level-1 PG, and let x2=N/x1 be the number of level-1 PGs (all variables are assumed to be continuous).
For a flat network, define ={α|α>1}. We assume the time complexity of computing a minimum cost path in a flat (non-hierarchical) network with z nodes is R1(z)=α0zα, where α0>0 and αε. For example, for Dijkstra's shortest path method we have a α=2.
Certain nodes are identified as border nodes. A level-1 border node of a PG is a lowest-level node which is an endpoint of a trunk linking the PG to another level-1 PG. For example, if each U.S. state is a level-1 PG, and if there is a trunk from switch a in Chicago to switch b in Denver, then a and b are level-1 border nodes. Define Γ={γ|0≦γ<1}. We assume the number of level-1 border nodes in a PG with x1 lowest-level nodes is bounded above by B1(x1)=γ0x1γ, where γ0>0 and γεΓ. The case where each PG has a constant number k of border nodes is modelled by choosing γ0=k and γ=0. The case where the border nodes are the (approximately 4√{square root over (x1)}) boundary nodes of a square grid of x1 switches is modelled by choosing γ0=4 and γ=½.
Define ={κ|0≦κ≦1}. We assume the total number of level-1 PGs, excluding the source level-1 PG, that the connection visits is bounded above by V1(x2)=κ0(x2κ−1), where κ0>0 and κε. Note that V1(1)=0, which means that in the degenerate case of exactly one level-1 PG, there are no PGs visited other than the source PG.
This functional form for V1(x2) is chosen since the expected distance between two randomly chosen points in a square with side length L is kL, where k depends on the probability model used: using rectilinear distance, with points uniformly distributed over the square, we have k=⅔; using Euclidean distance we have k=( 1/15)[2+√{square root over (2)}+5 log(√{square root over (2)}+1]≈0.521; with an isotropic probability model we have k=[(2√{square root over (2)}/(3π)]log(1+√{square root over (2)})≈0.264. If the x2 PGs are arranged in a square grid, a random connection will visit approximately κ√{square root over (x2)}PGs. Choosing κ0=k and κ=½, the total number of PGs visited is approximately κ0x2κ. Choosing κ0=1 and κ=1 models the worst case in which the path visits each level-1 PG.
The source node of a connection sees the x1 nodes in the source PG, and at most B1(x1) border nodes in each of the x2−1 non-source PGs. A path computation is performed by the entry border node of at most V1(x2) non-source PGs. In each non-source PG visited, the entry border node sees only the x1 nodes in its PG when computing a path across the PG (or a path to the destination node, in the case of the destination PG), and so the path computation time complexity at each entry border node is R1(x1). Hence the total path computation time is bounded above by R1(x1+(x2−1)B1(x1))+V1(x2)R1(x1)=α0[x1+(x2−1)γ0x1γ]α+κ0(x2κ−1)α0x1α. We ignore the constant factor α0. The optimization problem for a 2-level hierarchy is thus: minimize [x1+(x2−1)γ0x1γ]α+κ0x1α(x2κ−1) subject to x1x2=N.
We next transform this optimization problem to a convex optimization problem (which has a convex objection function, a convex feasible region, and any local minimum is also a global minimum. We approximate x2−1 by x2 and x2κ−1 by x2κ, yielding the objective function [x1+γ0x1γx2]α+κ0x1αx2κ, which also upper bounds the total path computation time. We rewrite the constraint x1x2=N as Nx1−1x2−1=1, which can be replaced by Nx1−1x2−1≦1, since the inequality must be satisfied as an equality at any solution of the optimization problem. Letting y=x1+γ0x1γx2 yields the optimization problem: minimize yα+κ0x1αx2κsubject to x1+γ0x1γx2≦y and Nx1−1x2−1≦1. The inequality constraint x1+γ0x1γx2≦y must be satisfied as an equality in any solution; we rewrite this constraint as x1y−1+γ0x1γx2y−1≦1. Let s1=log x1, s2=log x2, s=(s1, s2), and t=log y. Combining exponential terms, we obtain the optimization problem 2(N):
minimize f2(s, t)=eαt+κ0e(αs
subject to e(s
Ne(−s
Problem 2(N) it is a special type of convex optimization problem called a geometric program. Geometric programs are particularly well suited to engineering design, with a rich duality theory permitting particularly efficient solution methods.
The following algorithm determines values for s1 and s2 that solve the optimization problem 2(N). Thus, the algorithm determines the optimal x1(the optimal PG size) and the optimal x2(the optimal number of PGs).
For a three-level PNNI network, let N be the total number of lowest-level nodes, let x1 be the number of lowest-level nodes in each level-1 PG, x2 be the number of level-1 PGs in each level-2 PG, and x3 be the number of level-2 PGs. Thus x1x2x3=N.
As for H=2, we assume the complexity of routing in a flat network with z lowest-level nodes is R1(z)=α0zα, where α0>0 and αε.
As for H=2, certain nodes are identified as border nodes. A level-1 border node of a PG in a 3-level network is a lowest-level node which is an endpoint of a trunk linking the PG to another level-1 PG within the same level-2 PG. A level-2 border node of a PG in a 3-level network is a lowest-level node which is an endpoint of a trunk linking the PG to another level-2 PG within the same PNNI network. For example, suppose each country in the world is a level-2 PG, and each U.S. state is a level-1 PG. Then if there is a trunk from a switch a in Boston to a switch b in London, a and b are level-2 border nodes.
For h=1, 2, we assume that the number of level-h border nodes in a level-h PG with z lowest-level nodes is bounded above by Bh(z)=γ0zγ, where γ0>0 and γεΓ. Thus each level-1 PG has at most B1(x1)=γ0x1γlevel-1 border nodes, and each level-2 PG has at most B2(x1x2)=γ0(x1x2)γ level-2 border nodes.
We assume that the total number of level-2 PGs, excluding the source level-2 PG, that the connection visits is bounded above by V2(x3)=κo(x3κ1), where κ0>0 and κε. Note that V2(1)=0, which means that in the degenerate case where there is one level-2 PG, there are no level-2 PGs visited other than the source level-2 PG. We assume that the total number of level-1 PGs visited within the source level-2 PG, excluding the source level-1 PG, is bounded above by V1(x2)=κ0(x2κ−1).
The source node sees the x1 nodes in its level-1 PG, at most B1(x1) level-1 border nodes in each of the x2−1 level-1 PGs (excluding the source level-1 PG) in the same level-2 PG as the source, and at most B2(x1x2) level-2 border nodes in each of the x3−1 level-2 PGs (excluding the source level-2 PG) in the PNNI network. Thus the total number of nodes seen by the source is bounded above by
x1+(x2−1)B1(x1)+(x3−1)B2(x1x2)=x1+(x2−1)/γ0x1γ+(x3−1)γ0(x1x2)γ.
The time complexity of the source path computation is bounded above by
R1(x1+(x2−1)B1(x1)+(x3−1)B2(x1x2)).
The total path computation time for all the level-1 PGs in the source level-2 PG, excluding the source level-1 PG, is at most V1(x2)R1(x1). For z>0, define R2(z)=ω0zω. The total path computation time for each of the V2(x3) level-2 PGs visited (other than the source level-2 PG) is, by definition, f2*(x1x2), which by Theorem 2 is bounded above by R2(x1x2).
To minimize the upper bound on the total path computation time for a three-level net-work, we solve the optimization problem:
minimize R1(x1+(x2−1)B1(x1)+(x3−1)B2(x1x2))+V1(x2)R1(x1)+V2(x3)R2(x1x2)
subject to x1x2x3=N. We approximate x2−1 by x2, x3−1 by x3, x2κ−1 by x2κ, and x3κ−1 by x3κ, which preserves the upper bound. Introducing the variable y, we obtain the optimization problem: minimize α0yα+κ0x2κα0x1α+κ0x3κω0(x1x2)ω subject to x1+x2γ0x1Γ+x3γ0+(x1x2)γ≦y and Nx1−1x2−1x3−1≦1. Letting s1=log x1, s2=log x2, s3=log x3, s=(s1, s2, s3), and t=log y, we obtain the geometric program 3(N):
minimize f3(s, t)=α0eαt+α0κ0e(αs
subject to es
Ne(−s
The following algorithm determines values for s1, s2, and s3 that solve the optimization problem 3(N). Thus, the algorithm determines the optimal x1 (the optimal level-1 PG size), x2 (the optimal number of level-1 PGs in each level-2 PG), and x3 (the optimal number of level-2 PGs).
Define (α1, α2, α3, α4)=(ε2α+ε3ω, ε2κ+ε3ω, ε3κ, ε1α).
Various additional modifications of this invention will occur to those skilled in the art. All deviations from the specific teachings of this specification that basically rely on the principles and their equivalents through which the art has been advanced are properly considered within the scope of the invention as described and claimed.
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