24 research outputs found
404. Control of estrogen receptors in male and female rat anterior pituitary and hypothalamus
Different Regulatory Pathways of Endometrial Connexin Expression: Preimplantation Hormonal-Mediated Pathway Versus Embryo Implantation-Initiated Pathway1
Tissue Distribution, Metabolism, and Excretion of 2,4,4'-Trichlorobiphenyl (Cb-28) in the Rat
Inferring social networks from outbreaks
Abstract. We consider the problem of inferring the most likely social network given connectivity constraints imposed by observations of outbreaks within the network. Given a set of vertices (or agents) V and constraints (or observations) Si ⊆ V we seek to find a minimum loglikelihood cost (or maximum likelihood) set of edges (or connections) E such that each Si induces a connected subgraph of (V, E). For the offline version of the problem, we prove an Ω(log(n)) hardness of approximation result for uniform cost networks and give an algorithm that almost matches this bound, even for arbitrary costs. Then we consider the online problem, where the constraints are satisfied as they arrive. We give an O(n log(n))-competitive algorithm for the arbitrary cost online problem, which has an Ω(n)-competitive lower bound. We look at the uniform cost case as well and give an O(n 2/3 log 2/3 (n))-competitive algorithm against an oblivious adversary, as well as an Ω ( √ n)-competitive lower bound against an adaptive adversary. We examine cases when the underlying network graph is known to be a star or a path, and prove matching upper and lower bounds of Θ(log(n)) on the competitive ratio for them.