This submission is devoted to optimization of networks that permanently experience fluctuations

of the capacity available on their links. This is an important and novel topic since limited link availability is a fundamental feature in wireless networks and yet majority of

work in survivable network design is restricted to the total single link failures. We assume

a given finite set of network states. Each state is characterized by availability coefficients

specifying, for each link, the fraction of its reference capacity available in this state, and

by traffic coefficients specifying, for each demand, the proportion of its reference traffic to

be realized in the considered state. Our routing strategy allows for thinning/thickening the

reference path-flows, with the thickening limited by a given upper bound U of the reference

value. Thus, in each state, the value of every path-flow can range from 0 to U times its

reference value. For the corresponding link cost minimization problem (where link capacities

and state-dependent path-flows are decision variables) we present a non-compact linear programming

model together with a solution algorithm based on path generation. We illustrate

the effectiveness of the introduced routing strategy by presenting numerical results for a set

of representative network examples.