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arxiv: 2103.14974 · v2 · pith:NYTI5HNMnew · submitted 2021-03-27 · 🧮 math.OC · cs.LG· cs.MS· cs.NA· math.NA

Automatic differentiation for Riemannian optimization on low-rank matrix and tensor-train manifolds

classification 🧮 math.OC cs.LGcs.MScs.NAmath.NA
keywords riemannianlow-rankoptimizationautomaticdifferentiationgivengradientsimplementation
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In scientific computing and machine learning applications, matrices and more general multidimensional arrays (tensors) can often be approximated with the help of low-rank decompositions. Since matrices and tensors of fixed rank form smooth Riemannian manifolds, one of the popular tools for finding low-rank approximations is to use Riemannian optimization. Nevertheless, efficient implementation of Riemannian gradients and Hessians, required in Riemannian optimization algorithms, can be a nontrivial task in practice. Moreover, in some cases, analytic formulas are not even available. In this paper, we build upon automatic differentiation and propose a method that, given an implementation of the function to be minimized, efficiently computes Riemannian gradients and matrix-by-vector products between an approximate Riemannian Hessian and a given vector.

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