1,704 research outputs found
BPGrad: Towards Global Optimality in Deep Learning via Branch and Pruning
Understanding the global optimality in deep learning (DL) has been attracting
more and more attention recently. Conventional DL solvers, however, have not
been developed intentionally to seek for such global optimality. In this paper
we propose a novel approximation algorithm, BPGrad, towards optimizing deep
models globally via branch and pruning. Our BPGrad algorithm is based on the
assumption of Lipschitz continuity in DL, and as a result it can adaptively
determine the step size for current gradient given the history of previous
updates, wherein theoretically no smaller steps can achieve the global
optimality. We prove that, by repeating such branch-and-pruning procedure, we
can locate the global optimality within finite iterations. Empirically an
efficient solver based on BPGrad for DL is proposed as well, and it outperforms
conventional DL solvers such as Adagrad, Adadelta, RMSProp, and Adam in the
tasks of object recognition, detection, and segmentation
Optimization Methods for Inverse Problems
Optimization plays an important role in solving many inverse problems.
Indeed, the task of inversion often either involves or is fully cast as a
solution of an optimization problem. In this light, the mere non-linear,
non-convex, and large-scale nature of many of these inversions gives rise to
some very challenging optimization problems. The inverse problem community has
long been developing various techniques for solving such optimization tasks.
However, other, seemingly disjoint communities, such as that of machine
learning, have developed, almost in parallel, interesting alternative methods
which might have stayed under the radar of the inverse problem community. In
this survey, we aim to change that. In doing so, we first discuss current
state-of-the-art optimization methods widely used in inverse problems. We then
survey recent related advances in addressing similar challenges in problems
faced by the machine learning community, and discuss their potential advantages
for solving inverse problems. By highlighting the similarities among the
optimization challenges faced by the inverse problem and the machine learning
communities, we hope that this survey can serve as a bridge in bringing
together these two communities and encourage cross fertilization of ideas.Comment: 13 page
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