280 likes | 444 Views
Stochastic Network Interdiction. Udom Janjarassuk. Outline. Introduction Model Formulation Dual of the maximum flow problem Linearize the nonlinear expression Sample Average Approximation Decomposition Approach Computational Results Further Work. Introduction.
E N D
Stochastic Network Interdiction Udom Janjarassuk
Outline • Introduction • Model Formulation • Dual of the maximum flow problem • Linearize the nonlinear expression • Sample Average Approximation • Decomposition Approach • Computational Results • Further Work
Introduction • Network Interdiction Problem
Introduction (cont.) • Stochastic Network Interdiction Problem (SNIP) • Uncertain successful interdiction • Uncertain arc capacities • Goal: minimize the expected maximum flow • This is a two-stages stochastic integer program • Stage 1: decide which arcs to be interdicted • Stage 2: maximize the expected network flow • Applications • Interdiction of terrorist network • Illegal drugs • Military
Formulation • Directed graph G=(N,A) • Source node rN, Sink node tN • S = Set of finite number of scenarios • ps = Probability of each scenario • K = budget • hij = cost of interdicting arc (i,j)A
Formulation (cont.) where fs(x) is the maximum flow from r to t in scenario s
Formulation (cont.) • uij = Capacity of arc (i,j) A • A’ = A {r,t} • ijs = • yijs = flow on arc (i,j) in scenario s
Formulation (cont.) Maximum flow problem for scenario s
Formulation (cont.) The dual of the maximum flow problem for scenario s is Strong Duality, we have
Linearize the nonlinear expression • Linearize xijijs • Let zijs = xijijs xij = 0 zijs = 0 xij = 1 zijs = ijs • Then we have zijs – Mxij <= 0 – ijs+ zijs <= 0 ijs– zijs + Mxij<= M where M is an upper bound for ijs , here M = 1
Sample Average Approximation • Why? • Impossible to formulate as deterministic equivalent with all scenarios • Total number of scenarios = 2m, m = # of interdictable arcs • Sample Average Approximations • Generate N samples • Approximate f(x) by
Sample Average Approximation(cont.) • Lower bound on f(x)=v* • Confidence Interval
Sample Average Approximation(cont.) • The (1-)-confidence interval for lower bound Where P(N(0,1) z)=1-
Sample Average Approximation(cont.) • Upper bound on f(x) • Estimate of an upper bound (For a fixed x) • Generate T independent batches of samples of size N • Approximate by
Sample Average Approximation(cont.) • Confidence Interval • The (1-)-confidence interval for upper bound Where P(N(0,1) z)=1-
Decomposition Approach • Recall our problem in two-stages stochastic form
Decomposition Approach (cont.) • E[Q(x, s)] is piecewise linear, and convex • The problem has complete recourse – feasible set of the second-stage problem is nonempty • The solution set is nonempty • Integer variables only in first stage • Therefore, the problem can be solve by decomposition approach (L-Shaped method)
Computational results SNIP 4x9 example: Note: 1. Only arcs with capacity in ( ) are interdictable 2. The successful of interdiction = 75% 3. Total budget K = 6
Computational results (cont.) Note: Optimal objective value in [Cormican,Morton,Wood]=10.9 with error 1%
Computational results (cont.) SNIP 7x5 example:
Computational results (cont.) Note: Optimal objective value in [Cormican,Morton,Wood]=80.4 with error 1%
Further work… • Solving bigger instance on computer grid • Using Decomposition Approach