Within the context of stochastic probing with commitment, we consider the online stochastic matching problem; that is, the one-sided online bipartite matching problem where edges adjacent to an online node must be probed to determine if they exist based on edge probabilities that become known when an online vertex arrives. If a probed edge exists, it must be used in the matching (if possible). We consider the competitiveness of online algorithms in both the adversarial order model (AOM) and the random order model (ROM). More specifically, we consider a bipartite stochastic graph $G = (U,V,E)$ where $U$ is the set of offline vertices, $V$ is the set of online vertices and $G$ has edge probabilities $(p_{e})_{e \in E}$ and edge weights $(w_{e})_{e \in E}$. Additionally, $G$ has probing constraints $(\scr{C}_{v})_{v \in V}$, where $\scr{C}_v$ indicates which sequences of edges adjacent to an online vertex $v$ can be probed. We assume that $U$ is known in advance, and that $\scr{C}_v$, together with the edge probabilities and weights adjacent to an online vertex are only revealed when the online vertex arrives. This model generalizes the various settings of the classical bipartite matching problem, and so our main contribution is in making progress towards understanding which classical results extend to the stochastic probing model.
翻译:在有承诺的测试范围内,我们考虑在线随机排序模型(ROM)的竞争性。更具体地说,我们考虑的是单面在线双边匹配问题,即在线节点附近边缘的单面在线双方匹配问题,必须在这里对美元进行检测,以确定是否存在基于边缘概率的在线顶点到达时所知道的边缘概率。如果发现边缘存在,则必须用于匹配(如果可能的话)。我们考虑的是对称顺序模型(AOM)和随机排序模型(ROM)的在线算法的竞争力。更具体地说,我们考虑的是双面双面双面双面匹配图形($G=(U,V,E),其中美元是离线的顶点,美元是在线顶点的概率,美元和美元是在线的直径比值,而在线的直位是S(p), 直角值是Oral=creal=crequireal, 直线端是Screcial=xxxxxxx, rocrial roal roqual ex ex rocial ex ex ex ex,这是我们对Ol=sl=sl=xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx
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