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تسجيل مستخدم جديدNetwork Tomography: Identifiability and Fourier Domain Estimation
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The statistical problem for network tomography is to infer the distribution of $mathbf{X}$, with mutually independent components, from a measurement model $mathbf{Y}=Amathbf{X}$, where $A$ is a given binary matrix representing the routing topology of a network under consideration. The challenge is that the dimension of $mathbf{X}$ is much larger than that of $mathbf{Y}$ and thus the problem is often called ill-posed. This paper studies some statistical aspects of network tomography. We first address the identifiability issue and prove that the $mathbf{X}$ distribution is identifiable up to a shift parameter under mild conditions. We then use a mixture model of characteristic functions to derive a fast algorithm for estimating the distribution of $mathbf{X}$ based on the General method of Moments. Through extensive model simulation and real Internet trace driven simulation, the proposed approach is shown to be favorable comparing to previous methods using simple discretization for inferring link delays in a heterogeneous network.
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